JP6978448B2 - refrigerator - Google Patents

Description

The present invention relates to a refrigerator.

Patent Document 1 describes a refrigerator having a plurality of freezing chambers and two upper and lower storage containers inside one of the freezing chambers.

Japanese Unexamined Patent Publication No. 2015-145747

However, the above-mentioned Patent Document 1 discloses a lower container and an upper container having the same depth dimension in the freezing chamber. The upper opening of the lower container is covered with the upper container, and the inside of the lower container is indirectly cooled. As a result, when the door of the freezing chamber is pulled out, the upper container and the lower container are always pulled out of the refrigerator together, so that it is difficult to provide the usage according to the purpose of the user.
An object of the present invention is to provide a refrigerator having improved usability of a freezing room.

INDUSTRIAL APPLICABILITY The present invention is a partition member that separates an inner box, an outer box, a refrigerating chamber, an ice-making chamber below the refrigerating chamber, a freezing chamber next to the ice-making chamber, and the ice-making chamber and the freezing chamber. The lower container in the freezing chamber is supported by a frame extending in the front-rear direction from the door of the freezing chamber, and the frame is slidably supported with respect to the inner box and the partition member. In a refrigerator, an upper container having a depth shorter than that of the lower container is provided on the upper stage of the lower container, and when the door is closed, the upper container is supported by the lower container and the door is opened. When the upper container is pushed toward the back side with respect to the lower container, the upper container is supported not only by the lower container but also by the inner box and the partition member.

According to the present invention, it is possible to provide a refrigerator with improved usability of the freezing room.

It is an external perspective view which shows the refrigerator which concerns on this embodiment. It is a front view which shows the inside of a freezing room. FIG. 2 is a cross-sectional view taken along the line AA of FIG. It is an exploded perspective view which shows the cold air supply member. It is a top view which shows the cold air introduction member which distributes cold air to an ice making chamber and an upper freezing chamber. (A) is a sectional view taken along line BB of FIG. 1, and (b) is a sectional view taken along line CC of FIG. The perspective view which shows the inside of the upper freezing chamber 50. An exploded perspective view of the lower storage container 53, the upper storage container 54, the tray member 55, and the like. (A) is a right side view showing the first basic position in the positional relationship between the upper storage container 54 and the lower storage container 53 when the upper freezing chamber door 5 is fully opened. (B) is a right side view showing the second basic position in the positional relationship between the upper storage container 54 and the lower storage container 53 when the upper freezing chamber door 5 is fully opened. (C) is a right side view showing a state in which the upper storage container 54 is moved rearward from the first basic position when the upper freezing chamber door 5 is fully opened. (A) is a right side view showing the first basic position of the positional relationship between the upper storage container 54 and the lower storage container 53 when the upper freezing chamber door 5 is closed. (B) is a right side view showing the second basic position in the positional relationship between the upper storage container 54 and the lower storage container 53 when the upper freezing chamber door 5 is closed.

Hereinafter, embodiments for carrying out the present invention (the present embodiment) will be described. However, the present embodiment is not limited to the following contents, and can be arbitrarily modified and implemented without impairing the gist of the present invention. Further, in the following, the description will be described with reference to the direction shown in FIG.

FIG. 1 is an external perspective view showing a refrigerator according to the present embodiment.

As shown in FIG. 1, the refrigerator 100 includes a refrigerator main body 1, a freezing cycle F (see FIG. 3) that generates cold air for cooling the inside of the refrigerator main body 1, and a cold air supply member that supplies the generated cold air to the freezing chamber. (Cold air supply path) R (see FIG. 3).

The refrigerator 100 has a refrigerator room left door 2, a refrigerator room right door 3, an ice making room door 4, an upper freezer room door 5, a lower freezer room door 6, and a vegetable room door 7 in front of the refrigerator body 1. , Is equipped.

The refrigerating room left door 2 and the refrigerating room right door 3 are configured to be openable, and the refrigerating room 30 is formed in the space formed by these and the refrigerator main body 1.

Further, the ice making room door 4, the upper freezing room door 5, the lower freezing room door 6, and the vegetable room door 7 are configured to be able to be pulled out toward the front. Then, in the space formed by these and the refrigerator main body 1, an ice making room (first freezing room, freezing room) 40, an upper freezing room (second freezing room, freezing room) 50, a lower freezing room 60, and vegetables, respectively. A chamber 70 is formed.

The refrigerating room left door 2, the refrigerating room right door 3, the ice making room door 4, the upper freezing room door 5, the lower freezing room door 6 and the vegetable room door 7 are heat insulating doors. Each door 2 to 7 has, for example, an outer plate provided on the front surface, a door frame provided on the peripheral edge of the outer plate, an inner plate provided on the back surface (rear surface) of the door frame, and an outer plate and a door frame. It is configured to include a foaming heat insulating material formed by filling a space formed by the inner plate with a foaming liquid.

The foam insulation is made of rigid urethane foam. This rigid urethane foam is formed by foaming the urethane foam stock solution (raw material solution of the foamed heat insulating material) injected into the space inside each of the doors 2 to 7 and then curing the urethane foam. By the way, as the urethane foam undiluted solution, for example, a solution obtained by premixing a polyether polyol with a foaming agent such as cyclopentane and water, and an auxiliary agent such as a catalyst and a foam stabilizer, and an isocyanate solution are used. Can be mentioned.

The refrigerator main body 1 is a combination of an inner box 11 (see FIGS. 2 and 3) and an outer box 12, and a heat insulating member and a vacuum heat insulating material are sandwiched between them to form a heat insulating box body. The outer box 12 includes a top plate 1a formed by bending a thin steel plate into a gate shape, left and right side plates 1b and 1c (see FIG. 2 for the side plates 1c), and a back plate (not shown) composed of separate members. , A bottom plate (not shown) made of another member.

Further, the vacuum heat insulating material is provided on the back surface (inner wall surface) of the top plate 1a, the back surface (inner wall surface) of the side plates 1b and 1c, and the back surface (inner wall surface) of each door 2-7. The material of the vacuum heat insulating material is not particularly limited, but for example, it is made of a heat insulating material in which a core material such as glass wool having a porous structure is vacuum-packed with a laminated film and the inside is vacuum-packed and sealed. Since the gas thermal conductivity is almost zero, it has excellent heat insulation performance. Further, the vacuum heat insulating material is formed in a flat plate shape and is adhesively fixed to the top plate 1a, the side plates 1b, 1c, and the back surface side of each of the doors 2 to 7.

FIG. 2 is a front view showing the inside of the freezing chamber. Note that FIG. 2 shows only the freezing room (ice making room 40, upper freezing room 50 and lower freezing room 60), and the ice making room door 4, the upper freezing room door 5 and the lower freezing room door 6 are removed. Further, FIG. 2 illustrates the lower storage container 61, the middle storage container 62, and the upper storage container 63 stored in the lower freezing chamber 60, and the illustration of each storage container of the ice making chamber 40 and the upper freezing chamber 50 is omitted. There is.

As shown in FIG. 2, the refrigerator main body 1 extends in the left-right direction (width direction) between the ice making chamber 40 and the upper freezing chamber 50 and the lower freezing chamber 60 and is connected to the side plates 1b and 1c. The frame body 13 is provided. Further, the refrigerator main body 1 extends in the left-right direction (width direction) between the ice making chamber 40 and the upper freezing chamber 50 and the refrigerating chamber 30 (see FIG. 1), and is connected to the side plates 1b and 1c. It has a body 14. Further, the refrigerator main body 1 includes a frame body 15 extending in the vertical direction (vertical direction) between the ice making chamber 40 and the upper freezing chamber 50. Further, the frame body 15 is located between the frame body 13 and the frame body 14. Further, the refrigerator main body 1 is provided with a frame body 19 extending in the left-right direction (width direction) between the lower freezing chamber 60 and the vegetable compartment 70 (see FIG. 1) and connected to the side plates 1b and 1c. There is.

The ice making chamber 40 and the upper freezing chamber 50 are arranged side by side. Further, the volume of the ice making chamber 40 is smaller than that of the container of the upper freezing chamber 50.

The ice making chamber 40 is provided with rail members 41a and 41b that slidably support the ice making chamber door 4 in the front-rear direction. The rail member 41a is provided at the lower part of the left side surface of the inner box 11. The rail member 41b is provided on the lower right side of the ice making chamber 40.

The upper freezing chamber 50 is provided with rail members 51a, 51b that slidably support a pair of left and right door frames 52a, 52b provided on the back surface side of the upper freezing chamber door 5. The rail member 51a is provided in the lower left side (partition member 16) of the upper freezing chamber 50. The rail member 51b is provided on the lower side surface on the right side of the inner box 11.

The lower storage container 61, the middle storage container 62, and the upper storage container 63 are stored in the lower freezing chamber 60. The lower storage container 61 is held by an arm portion (not shown) extending rearward from both the left and right sides of the lower freezing chamber door 6 (see FIG. 1). The refrigerator main body 1 is provided with rail members 61a and 61b that make the lower storage container 61 slidable on the left and right side surfaces of the inner box 11. Further, in the refrigerator main body 1, rollers 61c and 61d for smoothing the sliding operation of the lower storage container 61 are rotatably supported on the front side of the rail members 61a and 61b.

In the lower freezing chamber 60, rail members 62a and 62b that slidably support the middle storage container 62 are provided on the left and right side surfaces of the inner box 11. Further, in the lower freezing chamber 60, rail members 63a and 63b that slidably support the upper storage container 63 are provided on the left and right side surfaces of the inner box 11.

FIG. 3 is a cross-sectional view taken along the line AA of FIG.

As shown in FIG. 3, a partition member (vertical partition member) 16 is provided between the ice making chamber 40 and the upper freezing chamber 50 (see FIG. 2). The partition member 16 is formed along the front-rear direction and is formed at a position overlapping the frame body 15 in the front-rear direction.

The partition member 16 extends linearly from the lower part of the back surface of the frame body 15 toward the rear. Further, the partition member 16 includes a rail support portion 16a in which the rail members 41b, 51a (see FIG. 2) are integrally formed, and connecting portions 16b, 16c, 16d extending upward from the rail support portion 16a. It is configured to have. In the partition member 16, the rail support portion 16a and the connecting portions 16b, 16c, 16d are integrally formed of synthetic resin.

The connecting portions 16b and 16c are fixed to the lower surface of the heat insulating partition member 17 that separates the refrigerating chamber 30 (see FIG. 1) and the freezing chamber (ice making chamber 40, upper freezing chamber 50). The connecting portion 16d is fixed to the lower surface of the second cold air introduction path 22c of the cold air supply member R described later. In the present embodiment, between the connecting portion 16b and the connecting portion 16c, between the connecting portion 16c and the connecting portion 16d, and between the connecting portion 16d and the cold air supply member R, the spaces s1, s2, and s3 are used. The ice making chamber 40 and the upper freezing chamber 50 are communicated with each other. However, the structure may be such that the ice making chamber 40 and the upper freezing chamber 50 do not communicate with each other and are separated by a wall.

Further, the ice making chamber 40, the upper freezing chamber 50, and the lower freezing chamber 60 communicate with each other via the space S4.

The lower storage container 61 stored in the lower freezing chamber 60 has a large capacity extending from the front end to the rear end. The middle storage container 62 has a shorter depth in the front-rear direction and is thinner than the lower storage container 61. The upper storage container 63 has a longer depth in the front-rear direction and is thinner than the middle storage container 62.

The refrigerating cycle F includes a compressor (not shown), a condenser (not shown), a capillary tube (decompressing means) 8, and a cooler (evaporator, evaporator) 9. The cooler 9 is housed in a cooler storage chamber 9s provided substantially behind the lower freezing chamber 60. A compressor (not shown) is installed in a machine room Q (see FIG. 1) provided in the lower part on the back side of the heat insulating box. The machine room Q is formed on the outside of the heat insulating box.

The cooler 9 includes a laminated body group in which copper fins 9a are arranged in five stages in the vertical direction in which laminated bodies in which copper fins 9a are arranged at minute intervals in the thickness direction (horizontal direction), and a refrigerant pipe penetrating each laminated body of the laminated body group. It is configured to include 9b.

Further, a defrost heater H is provided below the cooler 9. The drain water generated during defrosting by the defrost heater H once drops into the gutter 9c and is stored in an evaporating dish (not shown) provided at the top of the compressor (not shown) through the drain hole 9d. ..

Further, a blower fan 18 (propeller fan, axial flow fan) is provided above the cooler 9. The blower fan 18 sucks in the cold air (low temperature air) generated by the cooler 9 from the rear and discharges it toward the front. A fan cover 21 is attached to the blower fan 18, so that the cold air discharged from the blower fan 18 is diffused in the vertical and horizontal directions and supplied to the ice making chamber 40, the upper freezing chamber 50, the lower freezing chamber 60, and the like. It has become.

Further, the rear end 61e of the lower storage container 61 is located below the blower fan 18 in the vertical direction (vertical direction). Further, the upper end 9f of the cooler 9 is located below the upper end 61f of the lower storage container 61. Further, the blower fan 18 and the cooler 9 are housed below the ice making chamber 40 and the upper freezing chamber 50.

FIG. 4 is an exploded perspective view showing a cold air supply member.

As shown in FIG. 4, the cold air supply member R is configured by combining a fan base (base member) 20 to which a blower fan 18 is attached, a fan cover 21, and a cold air introduction member 22.

The fan base 20 includes a flat base portion 20t formed in a substantially pentagonal shape (substantially base type). Further, the fan base 20 includes a fan fixing portion 20a for fixing the blower fan 18 to the base portion 20t, and a cover locking portion 20d for locking the fan cover 21 to the base portion 20t. Further, the fan base 20 is provided with an intake port 20 g for taking in cold air in the freezer.

Further, the fan base 20 is fixed to the inner wall of the inner box 11 (see FIG. 2). Further, a cooler 9 (freezer compartment cooler) is arranged on the back side (back side) of the fan base 20. In other words, the cooler 9 is housed in the cooler storage chamber 9s formed between the inner box 11 and the outer box 12.

The fan fixing portion 20a has locking claws 20b, 20b, 20c, 20c for locking and fixing the blower fan 18. The blower fan 18 includes a blade 18a and a frame 18b having a rectangular outer shape that rotatably supports the center of the blade 18a. The frame 18b of the blower fan 18 is locked by these locking claws 20b, 20b, 20c, 20c.

The cover locking portion 20d includes a positioning rib 20e for positioning the fan cover 21 and a holding portion 20f that engages with the fan cover 21 to hold the fan cover 21. The positioning rib 20e is composed of a plurality of ribs 20e1, 20e2, 20e3, 20e4 formed so as to project forward from the base portion 20t.

The rib 20e1 is located on the left side of the blower fan 18 in the front view, and is formed so as to extend along the vertical direction. The rib 20e2 is formed with a gap s11 with respect to the rib 20e1 and extends in the horizontal direction (rightward direction) along the vertical direction to form an L shape. The rib 20e3 is formed with a gap s12 with respect to the rib 20e2, extends in the horizontal direction, and is formed in a straight line. The rib 20e4 is formed with a gap s13 with respect to the rib 20e3, and extends along the horizontal direction to the base 20t.

The holding portion 20f has a claw portion 20f1 formed at a position not overlapping with the rib 20e1 in the left-right direction, and a claw portion 20f2, 20f3, 20f4 formed in the respective gaps s11, s12, s13. Further, the claw portion 20f2 is arranged apart from the outside between the rib 20e1 and the rib 20e2. The claw portion 20f3 is arranged apart from the outside between the rib 20e2 and the rib 20e3. The claw portion 20f4 is arranged apart from the outside between the rib 20e3 and the rib 20e4.

The intake port 20g is a return port for cold air, is formed in a grid pattern, and is formed at the lower end of the base portion 20t. Further, the intake port 20g is located below the holding portion 20f and is formed elongated in the width direction (left-right direction) with respect to the base portion 20t.

The fan cover 21 is formed so as to project forward from the fan base 20, and a front portion 21a is formed at a position facing the blower fan 18. The back surface of the front portion 21a is exposed to the cold air discharged from the blower fan 18. Further, the front portion 21a is formed with a circular recess 21b facing the blower fan 18 in the center in the left-right direction (width direction). The recess 21b is formed so as to project rearward (so that the concave surface faces forward) (see FIG. 3). By forming the recess 21b, the cold air discharged from the blower fan 18 can be smoothly turned outward in the radial direction, and the blower efficiency can be suppressed from being impaired.

Further, an outer peripheral portion 21c extending from the outer peripheral edge portion of the front surface portion 21a toward the fan base 20 is formed. The length of the outer peripheral portion 21c is such that a predetermined gap s20 (see FIG. 3) can be formed between the blower fan 18 and the recess 21b when the fan cover 21 is attached to the fan base 20. Further, the predetermined gap s20 is a distance at which the cold air from the blower fan 18 can be discharged outward in the radial direction.

Further, the front portion 21a is formed so that a rectangular notch 21d opens upward above the recess 21b. Further, a plurality of discharge ports 21e1, 21, 21e2, 21f, 21g, 21g, 21h, 21i, 21i for discharging cold air are formed on the front portion 21a. The discharge ports 21e1, 21e2 are at the same height position as each other. The discharge ports 21f, 21g, and 21g are at the same height position as each other. The discharge ports 21h, 21i, 21i are at the same height position as each other.

The cold air introduction member 22 includes a cold air distribution unit 22a that distributes cold air to the ice making chamber 40 (see FIG. 2) and the upper freezing chamber 50 (see FIG. 2). Further, the cold air introduction member 22 includes a first cold air introduction path 22b for introducing cold air into the ice making chamber 40 (see FIG. 2) and a second cold air introduction path 22c for introducing cold air into the upper freezing chamber 50 (see FIG. 2). , Is equipped.

The cold air distribution unit 22a is a rectangular cylinder 22a1 connected to the notch 21d, and a wind direction plate 22a2 (which changes the direction of cold air to the ice making chamber 40 and the upper freezing chamber 50 at the upper end of the cylinder 22a1. It has a cold air distribution amount setting plate).

The first cold air introduction path 22b has a cold air guide path 22b1 extending from the upper end of the tubular body 22a1 toward the left side (the ice making chamber 40 side) and extending toward the front. The cold air guide path 22b1 is bifurcated at the tip and has a wide air passage 22b2 and an air passage 22b3 narrower than the air passage 22b2. Further, the tip of the air passage 22b2 is set at a position higher than the tip of the air passage 22b3. Further, in the air passage 22b2, an air passage 22b4 set lower than the tip of the air passage 22b2 is branched and formed.

By configuring the air passage 22b2 in this way, cold air is discharged from the upper end of the ice making chamber 40 toward the front. Further, the cold air is discharged from a position lower than the air passage 22b2 toward the ice making chamber 40 by the air passages 22b3 and 22b4.

The second cold air introduction path 22c has a cold air guide path 22c1 extending from the upper end of the tubular body 22a1 along the front side (partition member 16 (see FIG. 3)). The width of the air passage of the cold air guide passage 22c1 is formed to be substantially the same as the width of the partition member 16. Further, the cold air guide path 22c1 is formed with a notch 22c2 on the surface facing the upper freezing chamber 50 (see FIG. 2). That is, the cold air guide path 22c1 is formed with a side wall 22c3 that blocks the flow of cold air and a side wall 22c4 that blocks the flow of cold air toward the ice making chamber 40 (see FIG. 2) at the tip of the cold air guide path 22c1. ing. As described above, since the side wall on the upper freezing chamber 50 side of the cold air guide path 22c1 is formed lower than the other side walls 22c3 and 22c4 by the notch 22c2, it was introduced (distributed) into the cold air guide path 22c1. Cold air is discharged toward the upper freezing chamber 50 (see FIG. 2) through the notch 22c2.

FIG. 5 is a top view showing a cold air introducing member that distributes cold air to an ice making chamber and an upper freezing chamber.

As shown in FIG. 5, in the cold air introduction member 22, the flow path width W1 of the first cold air introduction path 22b is formed wider than the flow path width W2 of the second cold air introduction path 22c. In this way, by widening the flow path width W1 of the first cold air introduction path 22b, the amount of cold air introduced into the ice making chamber 40 can be increased. By changing the ratio of the flow path widths W1 and W2, the amount of cold air distributed to the ice making chamber 40 and the upper freezing chamber 50 can be easily adjusted. Further, by changing the shape of the wind direction plate 22a2, the amount of cold air distributed to the ice making chamber 40 and the upper freezing chamber 50 can be adjusted.

The cold air distribution unit 22a is formed so that the wind direction plate 22a2 covers substantially half of the opening of the tubular body 22a1 in a top view (planar view). The wind direction plate 22a2 is formed by bending the plate materials 22a3 and 22a4. The plate material 22a3 is arranged so as to rise toward the first cold air introduction path 22b. The plate material 22a4 is arranged so as to be inclined so as to rise toward the front side. The plate material 22a3 guides the cold air toward the first cold air introduction path 22b, and the plate material 22a4 guides the cold air toward the second cold air introduction path 22c.

Next, the configuration and the withdrawal operation of the lower storage container 53 and the upper storage container 54 provided in the upper freezing chamber 50 will be described with reference to FIGS. 6 to 10.

FIG. 6 is a cross-sectional view taken along the line BB of FIG. FIG. 7 is a perspective view showing the inside of the upper freezing chamber 50 in a state where the upper freezing chamber door 5 and the door frames 52a and 52b shown in FIG. 6 are removed. FIG. 8 is an exploded perspective view of the lower storage container 53, the upper storage container 54, the tray member 55, and the like shown in FIG.

As shown in FIGS. 6 and 8, a lower storage container 53 and an upper storage container 54 are provided in the upper freezing chamber 50. At this time, the dimension in the front-rear direction of the lower storage container 53 is configured to be larger than the dimension in the front-rear direction of the upper storage container 54. That is, the upper opening of the lower storage container 53 has a portion not covered by the upper storage container 54.

Further, the depth dimension of the lower storage container 53 was made larger than the depth dimension of the upper storage container 54. Foods with a relatively small height are stored in the upper storage container 54, foods with a large height are stored in the lower storage container 53, and the user can use them properly.

The lower storage container 53 is supported at the left and right bottoms by the door frames 52a and 52b provided on the upper freezing chamber door 5.

Further, the left and right door frames 52a and 52b are formed by a rail portion 51a provided on the lower side surface of the upper freezing chamber 50 side of the partition member 16 and a rail portion 51b provided on the lower side surface on the right side of the inner box 11, respectively. , Supports slidable in the front-back direction.

Further, as shown in FIGS. 6 and 8, sliding edge portions 53a and 53b are formed on the peripheral edge portion of the upper opening of the lower storage container 53.

The upper storage container 54 is provided with a convex first sliding portion 54a1 and a first sliding portion 54a2 in the front and rear at the lower part of one of the left and right side surfaces thereof, and the first sliding portion 54a2 is provided in the lower part of the other side surface. The moving portion 54b1 and the first sliding portion 54b2 are provided in the front-rear direction. These first sliding portions 54a1, 54a2, 54b1, 54b2 are supported by the sliding edge portions 53a, 53b of the lower storage container 53, respectively, and the upper storage container 54 is slidable in the front-rear direction.

Further, the upper storage container 54 is provided with a convex second sliding portion 54c1 and a second sliding portion 54c2 in the front and rear on the upper part of one of the left and right side surfaces thereof, and is provided on the upper part of the other side surface. Two sliding portions 54d1 and a second sliding portion 54d2 are provided. The second sliding portions 54c1 and 54c2 are slidably supported in the front-rear direction by the rail portions 51c provided on the partition member 16. The second sliding portions 54d1 and 54d2 are slidably supported in the front-rear direction by the rail portions 51d provided on the inner box 11.

In the present embodiment, the second sliding portions 54c1 and 54c2 are slidably supported by the rail portions 51c provided on the partition member 16 for partitioning the storage chamber to the left and right. It does not have to be limited to. For example, a component corresponding to the rail portion 51c may be suspended and attached to the surface of the heat insulating partition member 17 on the upper freezing chamber 50 side (ceiling surface of the upper freezing chamber 50) and supported from above. Further, a component corresponding to the rail portion 51c may be attached to the inner box 11A or the fan base 20 on the back of the upper freezing chamber 50 and supported from the rear.

Further, among the front, rear, left and right walls of the upper storage container 54, the height dimension of a part of the front wall 54e was lowered to form the handle portion 54e1. This makes it easier for the user's finger to enter when pulling out the upper storage container 54, and improves usability.

In the present embodiment, the front wall 54e is partially lowered to provide the handle portion 54e1, but the configuration is not limited to this. For example, a recess may be formed in the upper surface flange portion (not shown) of the front wall 54e, and the recess may be used as a handle portion.

Further, a thin tray member 55 is provided in the upper storage container 54. The tray member 55 is metallic, and a material having high thermal conductivity such as aluminum or stainless steel is preferable. At this time, since the upper storage container 54 has a small depth and the cold air from the cold air introduction unit 22 is directly sent, the cooling efficiency is higher than that of the lower storage container 53, so that the upper storage container 54 can be used as a rapid cooling chamber.

Further, a plurality of holes (not shown) may be provided on the bottom surface of the upper storage container 54. By having this hole, the storage space of the upper storage container 54 and the storage space of the lower storage container 53 communicate with each other, and the cold air flowing into the upper storage container 54 enters the lower storage container 53 through the hole. Can be guided.

Further, the tray member 55 is provided so as to cover the hole (not shown) from above. As a result, the cold air flowing into the upper storage container 54 is indirectly transferred to heat via the tray member 55, and the inside of the lower storage container 53 can be indirectly cooled.

Next, with reference to FIGS. 9 and 10, the sliding and position of the upper storage container 54 when the upper freezing chamber door 5 is fully opened and when the upper freezing chamber door 5 is closed will be described. FIG. 9 is a side view showing a state in which the upper freezing chamber door 5 of the refrigerator 1 shown in FIG. 1 is opened. 10A and 10B are side views in a state where the upper freezing chamber door 5 of the refrigerator 1 shown in FIG. 1 is closed and the side plate 1b is penetrated. FIGS. 9A to 9C are upper freezing chamber doors. It is a right side view which shows the state which pulled out 5 to the outside of a refrigerator.

FIG. 9A shows that the positional relationship between the upper storage container 54 and the lower storage container 53 is the state of the first basic position when the upper freezing chamber door 5 is opened.

The first basic position includes a front first convex portion 53a1, 53b1 for restricting the position of the first sliding portion 54a1, 54b1 to the first basic position, and a rear second convex portion 53a2, 53b2. The state between. At this time, since the first sliding portions 54a2 and 54b2 are supported by the sliding edge portions 53a and 53b, the upper storage container even if the second sliding portions 54c2 and 54d2 are not supported by the rail portions 51c and 51d. The 54 can be kept horizontal.

In the state of the first basic position, it is possible to store tall food in the storage space in the front portion of the lower storage container 53. Therefore, foods having a relatively small height may be stored in the upper storage container 54 or the back side of the lower storage container 53, and foods having a relatively large height may be stored in the front side of the lower storage container 53. It is possible to provide a convenient storage room according to the user's purpose.

The front first convex portions 53a1, 53b1 for the first basic position have a larger rear slope than a front slope. Further, since the second convex portions 53a2 and 53b2 at the rear have a larger inclination at the front than the inclination at the rear, there is less resistance when guiding the upper storage container 54 to the first basic position. Further, after the upper storage container 54 is guided to the first basic position, the resistance when sliding forward or backward from the first basic position is large, so that the state of the first basic position can be easily maintained.

Further, at the first basic position, the dimension D1 between the front wall 53e of the lower storage container 53 and the front wall 54e of the upper storage container 54 is larger than the height dimension H1 of the front wall 53e of the lower storage container 53. .. As a result, by securing a wide frontage of the storage space of the lower storage container 53, it becomes easier to put food in and out of the lower storage container 53, and usability can be improved.

As a means for restricting the position of the first sliding portions 54a1, 54b1 to the first basic position, a groove portion for restricting the movement of the first sliding portions 54a1, 54b1 may be formed. Therefore, a groove may be formed by providing a recess in the lower storage container 53 without providing the first convex portion 53a1, 53b1 or the second convex portion 53a2, 53b2 described above.

FIG. 9B shows that the positional relationship between the upper storage container 54 and the lower storage container 53 is the second basic position. That is, the upper storage container 54 is moved further forward than the first basic position shown in FIG. 9A, and the entire upper storage container 54 is out of the refrigerator.

The second basic position is a state in which the first sliding portion 54b1 (54a1) is positioned in front of the third convex portion 53b3 (53a3) for restricting the position to the second basic position. Since the third convex portion 53b3 (53a3) has a larger inclination in the front than the inclination in the rear, there is less resistance when guiding the upper storage container 54 to the second basic position. Further, after the upper storage container 54 is guided to the second basic position, the resistance when sliding the upper storage container 54 to the rear is larger than that of the second basic position, so that the state of the second basic position can be easily maintained. Instead of providing the convex portion 53b3 (53a3), the lower storage container 53 of the portion supported in the state of the second basic position may be recessed more than the other portions.

In the state of the second basic position, between the rear end of the upper storage container 54 and the front end of the refrigerator body 1 rather than the dimension D2 between the front wall 53e of the lower storage container 53 and the front wall 54e of the upper storage container 54. The dimension D3 of is increased. As a result, since everything from the front end to the rear end of the upper storage container 54 is outside the refrigerator body 1, it is possible to see the entire inside of the upper storage container 54, and it is easy to put in and take out food, which is convenient. good. Further, by reducing the dimension D2 between the front wall 53e of the lower storage container 53 and the front wall 54e of the upper storage container 54, cold air invades into the lower storage container 53 and the lower part when the upper freezing chamber door 5 is opened. The outflow of cold air to the outside of the storage container 53 can be suppressed.

9 (c) shows a state in which the upper storage container 54 is moved backward from the first basic position shown in FIG. 9 (a), and is in front of the front wall 53e of the lower storage container 53 and the upper storage container 54. The dimension D4 between the wall 54e and the wall 54e is larger than the dimension D1 shown in FIG. 9A.

In this state, the first sliding portions 54a2 and 54b2 provided on the rear side of the left and right side surfaces of the upper storage container 54 in the front-rear direction are located behind the sliding edge portions 53a and 53b. It becomes unsupported. Therefore, the second sliding portion 54c2 is supported by the rail portion 51c provided on the partition member 16, and the second sliding portion 54d2 is supported by the rail portion 51d provided on the inner box 11 (FIGS. 6 and 6 and). (See FIG. 7), the upper storage container 54 can be kept horizontal.

Further, the locking portion 54 g (shown in FIG. 6) of the upper storage container 54 abuts on the rear wall of the lower storage container 53, thereby limiting the amount of movement of the upper storage container 54 to the rear, and the upper storage container 54. Suppresses the dropout.

In the state of FIG. 9C, by moving the upper storage container 54 further rearward from the first basic position, the dimension D4 between the front wall of the lower storage container 53 and the front wall of the upper storage container is increased. can. That is, since the upper storage container 54 can be moved further rearward than the first basic position, the food stored in the inner part of the lower storage container 53 can be easily taken out, and the usability can be improved.

10 (a) and 10 (b) show a side view of the lower storage container 53, the upper storage container 54, and the frame member 52b in the upper freezing chamber 50 with the upper freezing chamber door 5 closed. It is a figure (the partition member 16 is omitted).

FIG. 10A shows a state in which the upper freezing chamber door 5 is closed when the lower storage container 53 and the upper storage container 54 are in the first basic position. When the upper freezing chamber door 5 is pulled forward and opened while maintaining this first basic position, the positions of the first sliding portions 54a1, 54b1 in the front-rear direction are the first convex portions 53a1, 53b1 and the second convex portions 53a2. , 53b2, so that the lower storage container 53 and the upper storage container 54 can be pulled out of the refrigerator while maintaining the state of the first basic position (that is, the state shown in FIG. 9A). Become).

Further, after the upper freezing chamber door 5 is pulled out and opened (that is, the state shown in FIG. 9A), the upper freezing chamber door 5 is moved backward while the lower storage container 53 and the upper storage container 54 remain in the first basic positions. When the first sliding portion 54a1, 54b1 is closed, the position of the first sliding portion 54a1, 54b1 in the front-rear direction is maintained between the front convex portion first a1,53b1 and the second convex portion 53a2, 53b2, and is shown in FIG. 10 (a). It can be in the state shown.

As a result, a space A capable of storing tall food can be formed in the storage space (between the front wall 53e of the lower storage container 53 and the front wall 54e of the upper storage container 54) in the front portion of the lower storage container 53. At the same time, it is possible to form storage spaces of three different heights, such as a space B that can store low-height foods and a space C that is higher than the space B and lower than the space A, and the usability can be improved.

FIG. 10B shows a state in which the upper freezing chamber door 5 is closed when the lower storage container 53 and the upper storage container 54 are in the second basic position. When the upper freezing chamber door 5 is pulled forward and opened while maintaining this second basic position, the positions of the first sliding portions 54a1 and 54b1 are maintained by the third convex portions 53a3 and 53b3 so as not to move backward. Therefore, the lower storage container 53 and the upper storage container 54 can be pulled out of the refrigerator while maintaining the state of the second basic position (that is, the state shown in FIG. 9B). As a result, the upper freezing chamber door 5 can be opened and closed while maintaining a state in which the entire upper storage container 54 can be seen, which is convenient. Further, the opening / closing operation of the upper freezing chamber door 5 can be performed while maintaining the state in which the cold air from the cold air introducing portion 22 can be directly sent into the lower storage container 53.

When the upper freezing chamber door 5 is closed in the state shown in FIG. 9 (c), the front-rear positions of the lower storage container 53 and the upper storage container 54 are in the state shown in FIG. 10 (a) (that is, the first basic). Position). After that, when the upper freezing chamber door 5 is pulled out and opened, it can be pulled out in the first basic position as described above, so that the user does not return the position of the upper storage container 54 when opening and closing the upper freezing chamber door 5. Since both are in the first basic position, troublesome operations are not required.

As described above, according to the present embodiment, the upper storage container 54, which is shorter in the front-rear direction than the lower storage container 53, is slidably provided on the upper part of the lower storage container 53. As a result, foods of three different heights can be stored separately in the upper and lower storage containers in one storage chamber, and a refrigerator that is easy to use according to the user's application can be provided.

Although the present embodiment has been described above with reference to the drawings, the present embodiment is not limited to the above contents. Therefore, the present invention includes various modifications. That is, the above-described embodiment has been described in detail in order to explain the present invention in an easy-to-understand manner, and is not necessarily limited to the one including all the configurations described.

Further, in the present embodiment, the case where the cooler 9 for cooling the freezer chamber and the cooler 31 for cooling the refrigerating chamber 30 are separately configured has been described as an example, but as in the conventional case, the freezer compartment is described. A cooler for cooling the refrigerating chamber 30 and the freezing chamber may be provided on the back surface of the refrigerator.

1 Refrigerator body (insulated box body)
5 Upper freezing room door 9 Cooler (freezing room cooler)
16 Partition member 17 Insulation partition member 17a Gutter 18 Blower fan 21 Fan cover 21s Drainage hole 22 Cold air introduction member 22a Cold air distribution unit 22b 1st cold air introduction path 22c 2nd cold air introduction path 30 Refrigerator room 31 Cooler )
40 Ice making room (1st freezing room, freezing room)
50 Upper freezing room (second freezing room, freezing room)
51a, 51b, 51c, 51d Rail part 52a, 52b Door frame 53 Lower storage container 53a, 53b Sliding edge part 53a1, 53b1 First convex part 53a2, 53b2 Second convex part 53a3, 53b3 Third convex part 53e Lower storage container Front wall 54 Upper storage container 54a1, 54a2, 54b1, 54b2 First sliding part 54c1, 54c2, 54d1, 54d2 Second sliding part 54e Front wall of upper storage container 54e1 Handle part 54g Locking part 55 Tray member 60 Lower freezing room (lower freezing room, freezing room)
61 Lower storage container (case)
61a Rear end 70 Vegetable room 100 Refrigerator F Refrigerator cycle R Cold air supply member (cold air supply path)

Claims (4)

Inner box, outer box,
It is provided with a refrigerating chamber, an ice making chamber at the lower stage of the refrigerating chamber, a freezing chamber next to the ice making chamber, and a partition member for partitioning the ice making chamber and the freezing chamber.
The lower container in the freezing chamber is supported by a frame extending in the front-rear direction from the door of the freezing chamber.
The frame is in a refrigerator slidably supported with respect to the inner box and the partition member.
An upper container having a shorter depth than the lower container is provided on the upper stage of the lower container.
When the door is closed, the upper container is supported by the lower container.
A state in which the door is opened, Push the upper container to the lower container on the rear side, when the rear end of the upper container is pushed further rearward than the rear end of the lower container, wherein The upper container is supported not only by the lower container but also by the inner box and the partition member .
When the door is closed with the rear end of the upper container pushed rearward from the rear end of the lower container, the upper container is returned forward with respect to the lower container to become the first basic position. When the door is opened in this state, the lower container and the upper container are pulled out from the freezing chamber while the upper container maintains the first basic position with respect to the lower container, and the upper container is further referred to as the first. It is possible to move forward from one basic position,
When the door is closed when the upper container is in the state of the first basic position with respect to the lower container after opening the door, the lower container and the upper container maintain the first basic position. Refrigerator, characterized in Rukoto the door is closed in the state. In claim 1,
When the door is closed when the upper container is moved forward from the first basic position and is in the state of the second basic position with respect to the lower container, the lower container and the upper container move to the second basic position. When the door is closed in the maintained state and the door is opened in this state, the lower container and the upper container are frozen while the upper container maintains the second basic position with respect to the lower container. refrigerator characterized by Rukoto drawn from the chamber. In claim 1 or 2,
The lower container has a groove portion that supports the sliding portion of the upper container at the first basic position, and the wall of the groove portion is inclined. The refrigerator according to claim 3, wherein the front wall of the upper container can be moved to a position close to the front wall of the lower container.

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