JP7220897B2 - Shielding device and refrigerator with same - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shielding device and a refrigerator having the shielding device, and more particularly to a shielding device and a refrigerator including the shielding device that appropriately blocks an air passage leading from a cooling chamber to a storage compartment.

2. Description of the Related Art Conventionally, there has been known a refrigerator in which a single cooler appropriately cools a plurality of storage compartments, as described in Patent Document 1.

FIG. 39 schematically shows the refrigerator 100 described in this document. A refrigerator 100 shown in this figure has a refrigerator compartment 101, a freezer compartment 102 and a vegetable compartment 103 from above. A cooling chamber 104 in which a cooler 108 is housed is formed on the far side of the freezing chamber 102, and a partition wall 105 separating the cooling chamber 104 and the freezing chamber 102 supplies cold air to each storage chamber. An opening 106 is formed for this purpose. A blower fan 107 for blowing cold air is arranged in the opening 106 , and a blower cover 110 covering the blower fan 107 is arranged on the freezer compartment 102 side. A damper 114 is arranged in the middle of the air passage 109 through which cold air supplied to the refrigerator compartment 101 flows.

Referring to FIG. 40, blower cover 110 described above will be described in detail. Blower cover 110 is formed with a recess 111 having a substantially rectangular shape, and an opening 113 is formed by partially notching the upper portion of recess 111 . Here, when the blower cover 110 covers the blower fan 107 described above, the opening 113 of the blower cover 110 communicates with the air passage 109 on the refrigerator main body side.

The refrigerator 100 configured as described above operates as follows. First, when cooling both the refrigerator compartment 101 and the freezer compartment 102, the blower cover 110 is separated from the blower fan 107, the damper 114 is opened, and the blower fan 107 is rotated in this state. Then, part of the cool air cooled by the cooler 108 inside the cooling chamber 104 is blown to the freezer compartment 102 by the blowing force of the blower fan 107 . Another part of this cold air is sent to refrigerator compartment 101 via air passage 109 , damper 114 and air passage 109 . Both the freezer compartment 102 and the refrigerator compartment 101 are thereby cooled.

On the other hand, when only refrigerating compartment 101 is cooled, blower fan 107 is covered with blower cover 110, damper 114 is opened, and cold air cooled by cooler 108 is blown by blower fan 107 in this state. When the fan cover 110 is closed, the opening 113 formed in the upper part of the fan cover 110 communicates with the air passage 109 . Therefore, cold air blown by the blower fan 107 is supplied to the refrigerator compartment 101 via the opening 113 , the damper 114 and the air passage 109 described above.

As described above, by using the blower cover 110 in which the opening 113 is formed, it is possible to appropriately cool a plurality of storage compartments with one cooler 108 .

JP 2013-2664 A

However, blower cover 110 configured as described above closes opening 106 of cooling chamber 104 by moving backward, and opens opening 106 of cooling chamber 104 by moving forward. In order to realize this movement, a drive mechanism for moving the fan cover 110 in the front-rear direction is required. Therefore, if cold air is blown to the drive mechanism, the drive mechanism may freeze, making it impossible to open and close the fan cover 110 .

Furthermore, the blower cover 110 requires a space for opening and closing operations along the front-rear direction. Therefore, a large space is required inside refrigerator 100 for opening and closing operation of fan cover 110 . As a result, the internal volume of the freezer compartment 102 formed in front of the blower cover 110 is squeezed, and there is a problem that the amount of the stored material that can be stored in the freezer compartment 102 is limited. Furthermore, when the blower cover 110 is moved back and forth by the motor, driving noise is generated, and if the driving noise is loud, the user may feel uncomfortable.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a shielding device that does not compress the internal volume of the refrigerator and produces a low driving noise, and a refrigerator equipped with the shielding device.

The present invention is a shielding device for blocking an air passage through which cold air is blown inside a refrigerator, comprising a plurality of rotating shielding walls surrounding a fan from the outside in the radial direction, and a shielding wall driving mechanism for driving the rotating shielding walls. and the shielding wall drive mechanism includes a rotating plate having a slide groove formed along the circumference, and a moving shaft engaging with the slide groove formed on the rotating shielding wall. a plurality of cams that can be connected together and a motor that rotates the rotating plate; the moving shafts of the plurality of cams are engaged with one of the slide grooves; A plate-like support base is provided between the shield wall driving mechanism .

Further, in the shielding device of the present invention, the cam has a first cam and a second cam, the first sliding range in which the first cam slides in the slide groove, and the second cam overlaps with a second sliding range in which the slide groove is slid.

Also, in the shielding device of the present invention, the slide groove is formed in an annular shape.

Also, in the shielding device of the present invention, the slide groove is formed in an incomplete ring shape.

Also, in the shielding device of the present invention, the slide groove has a first slide groove and a second slide groove formed inside the first slide groove in the radial direction.

Further, in the shielding device of the present invention, the motor rotates the rotating plate through a gear that meshes with a gear groove formed around the rotating plate, and a part of the periphery of the rotating plate has the It is characterized in that no gear groove is formed.

Further, the refrigerator of the present invention includes a refrigerating cycle cooler for cooling the air supplied to the storage compartment through the air passage, and an air outlet provided with the cooler and connected to the storage compartment. the air blower that blows the air supplied from the air blow port toward the storage chamber; and the shielding device that at least partially blocks the air passage. .

The present invention is a shielding device for blocking an air passage through which cold air is blown inside a refrigerator, comprising a plurality of rotating shielding walls surrounding a fan from the outside in the radial direction, and a shielding wall driving mechanism for driving the rotating shielding walls. and the shielding wall drive mechanism includes a rotating plate having a slide groove formed along the circumference, and a moving shaft engaging with the slide groove formed on the rotating shielding wall. a plurality of cams that can be connected together and a motor that rotates the rotating plate; the moving shafts of the plurality of cams are engaged with one of the slide grooves; A plate-like support base is provided between the shield wall drive mechanism . As a result, according to the shielding device of the present invention, the rotation shielding wall is opened and closed by the cam that slides when the rotating plate rotates, so that the shielding device can be thinned and a large internal volume of the storage chamber can be ensured. Further, by engaging the moving shafts of a plurality of cams with one slide groove, the meandering shape of the slide groove can be smoothed. Therefore, the sliding motion between the slide groove and the moving shaft and the rotating motion of the rotation blocking wall can be performed smoothly. Furthermore, the number of slide grooves can be reduced, and the construction of the shielding device can be simplified.

Further, in the shielding device of the present invention, the cam has a first cam and a second cam, the first sliding range in which the first cam slides in the slide groove, and the second cam overlaps with a second sliding range in which the slide groove is slid. Thus, according to the shielding device of the present invention, since the first sliding range and the second sliding range overlap each other, a large sliding range of the moving shaft of each cam can be ensured, and the slide groove and the moving shaft It is possible to perform the sliding motion with and the rotating motion of the rotating shielding wall more smoothly.

Also, in the shielding device of the present invention, the slide groove is formed in an annular shape. Thus, according to the shielding device of the present invention, the configuration of the shielding wall drive mechanism can be simplified by forming the slide groove in an annular shape.

Also, in the shielding device of the present invention, the slide groove is formed in an incomplete ring shape. Thus, according to the shielding device of the present invention, the initial position of the rotary plate can be easily detected by sliding the engaging portion of the cam to the end of the slide groove.

Also, in the shielding device of the present invention, the slide groove has a first slide groove and a second slide groove formed inside the first slide groove in the radial direction. Thus, according to the shielding device of the present invention, the rotary shielding wall is rotated by the cam whose engaging portion engages with the first slide groove, and the cam is rotated by the cam whose engaging portion engages with the second slide groove. It is possible to diversify the control method of the rotating shielding wall by making the control system different for the rotating shielding wall that moves.

Further, in the shielding device of the present invention, the motor rotates the rotating plate through a gear that meshes with a gear groove formed around the rotating plate, and a part of the periphery of the rotating plate has the It is characterized in that no gear groove is formed. Thus, according to the shielding device of the present invention, by rotating the rotating plate to the end of the gear groove, it is possible to easily detect the position of the rotating plate in the rotating direction.

Further, the refrigerator of the present invention includes a refrigerating cycle cooler for cooling the air supplied to the storage compartment through the air passage, and an air outlet provided with the cooler and connected to the storage compartment. the air blower that blows the air supplied from the air blow port toward the storage chamber; and the shielding device that at least partially blocks the air passage. . As a result, according to the refrigerator of the present invention, by providing a thin shielding wall blower having a plurality of rotating shielding walls surrounding the blower from the outside in the radial direction, the volume occupied by the shielding device can be reduced, The internal volume can be increased. In addition, the smooth opening and closing operation of the rotating shielding wall enables the operation of switching the ventilation of each storage room to be performed smoothly.

BRIEF DESCRIPTION OF THE DRAWINGS It is a front view which shows the external appearance of the refrigerator which concerns on embodiment of this invention. It is a side cross-sectional view showing the internal configuration of the refrigerator according to the embodiment of the present invention. Fig. 3 is an enlarged side cross-sectional view showing the structure around the cooling chamber of the refrigerator according to the embodiment of the present invention; 1 is a diagram showing a state in which a shielding device employed in a refrigerator according to an embodiment of the present invention is assembled, (A) is a perspective view of the shielding device as seen from the rear, and (B) is a front view of the shielding device. Figure 2 is a viewed perspective view; 1 is an exploded perspective view showing a shielding device according to an embodiment of the present invention; FIG. BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the shielding apparatus and refrigerator which concern on embodiment of this invention, (A) is sectional drawing which shows the state with which the shielding apparatus was assembled|attached, (B) is a front view which shows a partition. BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the shielding apparatus which concerns on embodiment of this invention, (A) is an exploded perspective view which shows a shielding apparatus, (B) is a perspective view which shows a cam. BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the shielding device which concerns on embodiment of this invention, (A) is an exploded perspective view which shows partially a shielding device, (B) is an exploded perspective view which shows the structure in which a cam is accommodated. It is a figure showing a shielding device concerning an embodiment of the present invention, (A) is a figure showing a rotation shielding wall of a shielding device seen from the back, and (B) shows the composition of a rotation plate seen from the back. It is a diagram. 1 is a view showing a fully closed state of a shielding device according to an embodiment of the present invention, where (A) is a view showing the shielding device as seen from the rear, and (B) is a view showing the rotating plate as seen from the rear. , (C) is a cut-away perspective view of the shielding device; It is a diagram showing a fully opened state of the shielding device according to the embodiment of the present invention, (A) is a diagram showing the shielding device as seen from the rear, (B) is a diagram showing the rotating plate as seen from the rear, (C) is a cutaway perspective view of the shielding device. FIG. 2A is a view showing the pattern 1 in the shielding device according to the embodiment of the present invention as seen from the rear, FIG. 1A is a view showing the shielding device, and FIG. FIG. 10 is a diagram showing the situation of the airflow path of pattern 1 in the shielding device according to the embodiment of the present invention, as viewed from the rear; FIG. 2A is a view showing the state of a pattern 2 in the shielding device according to the embodiment of the present invention as seen from the rear, FIG. 4A is a view showing the shielding device, and FIG. FIG. 10 is a diagram showing the situation of the pattern 2 air passage in the shielding device according to the embodiment of the present invention, as viewed from the rear; FIG. 2A is a view showing the state of the pattern 3 in the shielding device according to the embodiment of the present invention as seen from the rear, FIG. 4A is a view showing the shielding device, and FIG. FIG. 10 is a diagram showing the state of the airflow path of pattern 3 in the shielding device according to the embodiment of the present invention, as viewed from the rear; FIG. 2A is a view showing the state of a pattern 4 in a shielding device according to an embodiment of the present invention as seen from the rear, FIG. 4A is a view showing the shielding device, and FIG. FIG. 10 is a diagram showing the state of the airflow path of Pattern 4 in the shielding device according to the embodiment of the present invention, as viewed from the rear. FIG. 2A is a view showing the state of a pattern 5 in a shielding device according to an embodiment of the present invention as seen from the rear, FIG. 4A is a view showing the shielding device, and FIG. FIG. 10 is a diagram showing the situation of the airflow path of Pattern 5 in the shielding device according to the embodiment of the present invention, as viewed from the rear. FIG. 10 is a diagram showing the state of the pattern 6 in the shielding device according to the embodiment of the present invention as seen from the rear, where (A) is a diagram showing the shielding device and (B) is a diagram showing the rotating plate. FIG. 10 is a diagram showing the state of the airflow path of Pattern 6 in the shielding device according to the embodiment of the present invention, as viewed from the rear. FIG. 4 is a view showing the state of the pattern 7 viewed from the rear in the shielding device according to the embodiment of the present invention, where (A) is a view showing the shielding device and (B) is a view showing the rotating plate. FIG. 10 is a diagram showing the state of the airflow path of pattern 7 in the shielding device according to the embodiment of the present invention, as viewed from the rear. FIG. 2A is a view showing the state of a pattern 8 in a shielding device according to an embodiment of the present invention as seen from the rear, FIG. 4A is a view showing the shielding device, and FIG. FIG. 10 is a diagram showing the state of the airflow path of pattern 8 in the shielding device according to the embodiment of the present invention, as viewed from the rear. FIG. 10 is a diagram showing the state of the pattern 9 in the shielding device according to the embodiment of the present invention as seen from the rear, where (A) is a diagram showing the shielding device and (B) is a diagram showing the rotating plate. FIG. 10 is a diagram showing the situation of the air passage of Pattern 9 in the shielding device according to the embodiment of the present invention, as viewed from the rear. FIG. 2A is a view showing the pattern 10 in the shielding device according to the embodiment of the present invention as seen from the rear, FIG. 1A is a view showing the shielding device, and FIG. FIG. 10 is a diagram showing the state of the air passage of the pattern 10 in the shielding device according to the embodiment of the present invention, viewed from the rear. FIG. 2A is a view showing the state of a pattern 11 in a shielding device according to an embodiment of the present invention as seen from the rear, FIG. 1A is a view showing the shielding device, and FIG. FIG. 10 is a diagram showing the state of the air passage of the pattern 11 in the shielding device according to the embodiment of the present invention, viewed from the rear. FIG. 2A is a view showing the pattern 12 in the shielding device according to the embodiment of the present invention as seen from the rear, FIG. FIG. 10 is a diagram showing the state of the airflow path of the pattern 12 in the shielding device according to the embodiment of the present invention, viewed from the rear. FIG. 4 is a rear view showing the first sliding range and the second sliding range in the shielding device according to the embodiment of the present invention; It is a figure showing a shielding device concerning other forms of the present invention, and (A) and (B) are the figures which looked at the shielding device from the back. FIG. 11 is a rear view of a shielding device according to still another embodiment of the present invention; It is an enlarged side view showing a refrigerator according to background art. It is a perspective view which shows the fan cover employ|adopted by the refrigerator which concerns on background art.

Shielding device 70 and refrigerator 10 according to embodiments of the present invention will be described in detail below with reference to the drawings. In the following description, the same reference numerals are given to the same members in principle, and repeated descriptions will be omitted. Furthermore, in the following description, each direction of up, down, front, back, left, and right is appropriately used, and left and right indicate left and right when the refrigerator 10 is viewed from the rear. Furthermore, in the following description, the rotation directions are expressed as clockwise and counterclockwise, but these rotation directions indicate the directions when refrigerator 10 is viewed from the rear.

FIG. 1 is a front external view showing a schematic structure of a refrigerator 10 of this embodiment. As shown in FIG. 1, the refrigerator 10 has an insulating box body 11 as a main body, and the inside of the insulating box body 11 forms a storage chamber for storing food and the like. The storage compartments include a refrigerator compartment 15 at the top, an upper freezer compartment 18 at the bottom, a lower freezer compartment 19 at the bottom, and a vegetable compartment 20 at the bottom. Both the upper freezer compartment 18 and the lower freezer compartment 19 are storage compartments in the freezing temperature range, and may be collectively referred to as the freezer compartment 17 in the following description. Here, the upper freezer compartment 18 may be divided into left and right, and one side may be used as an ice making compartment.

The front surface of the heat insulating box 11 is open, and heat insulating doors 21 and the like are provided in openings corresponding to the respective storage compartments so as to be openable and closable. The heat-insulating door 21 divides the front surface of the refrigerating chamber 15 in the left-right direction and closes it. The heat insulating doors 23 , 24 , 25 are each integrally combined with the storage container and supported by the heat insulating box body 11 so as to be able to be pulled out to the front of the refrigerator 10 . Specifically, the heat insulation door 23 closes the upper freezer compartment 18 , the heat insulation door 24 closes the lower freezer compartment 19 , and the heat insulation door 25 closes the vegetable compartment 20 .

FIG. 2 is a side sectional view showing a schematic structure of the refrigerator 10. As shown in FIG. A heat insulating box body 11, which is a main body of a refrigerator 10, is composed of an outer box 12 made of steel plate with an open front surface and an inner box 13 made of synthetic resin with an open front surface and arranged with a gap in the outer box 12. - 特許庁It consists of A gap between the outer box 12 and the inner box 13 is filled with a heat insulating material 14 made of foamed polyurethane. The heat insulating door 21 and the like described above also employ the same heat insulating structure as the heat insulating box body 11 .

The refrigerator compartment 15 and the freezer compartment 17 positioned below it are partitioned by a heat insulating partition wall 42 . Cool air, which is cooled air, communicates freely between the upper freezer compartment 18 and the lower freezer compartment 19 provided therebelow. The freezer compartment 17 and the vegetable compartment 20 are separated by a heat insulating partition wall 43 .

A refrigerating chamber supply air passage 29 is formed on the rear surface of the refrigerating chamber 15 as a supply air passage for supplying cool air to the refrigerating chamber 15 , which is partitioned by a synthetic resin partition 65 . An air outlet 33 for supplying cool air to the refrigerating chamber 15 is formed in the refrigerating chamber supply air passage 29 .

A freezer compartment supply air passage 31 is formed on the far side of the freezer compartment 17 to flow cold air cooled by the cooler 45 to the freezer compartment 17 . A cooling chamber 26 is formed on the farther side of the freezer compartment supply air passage 31, and a cooler 45, which is an evaporator for cooling the air circulating inside the refrigerator, is arranged inside the cooling chamber 26. . The freezer compartment supply air passage 31 is a space surrounded by the front cover 67 and the partition 66 in the front-rear direction.

The cooler 45 is connected to the compressor 44, a radiator (not shown), and a capillary tube (not shown) as an expansion means through refrigerant pipes, and constitutes a vapor compression refrigeration cycle circuit.

FIG. 3 is a side cross-sectional view showing the structure around the cooling chamber 26 of the refrigerator 10. As shown in FIG. The cooling chamber 26 is provided inside the heat insulating box 11 and on the far side of the freezer compartment supply air passage 31 . The cooling chamber 26 and the freezing chamber 17 are separated by a synthetic resin partition 66 .

The freezer compartment supply air passage 31 formed in front of the cooling chamber 26 is a space formed between the cooling chamber 26 and a synthetic resin front cover 67 assembled in front thereof, and is cooled by the cooler 45. It becomes an air path for flowing cool air to the freezer compartment 17 . The front cover 67 is formed with a blowout port 34 that is an opening through which cold air is blown out to the freezer compartment 17 .

A return port 38 for returning air from the freezing chamber 17 to the cooling chamber 26 is formed in the lower back surface of the lower freezing chamber 19 . A return port 28 is formed in the lower part of the cooling chamber 26 to connect to the return port 38 and suck the return cold air from each storage chamber into the cooling chamber 26 . Cold air returning via a return port 39 (see FIG. 2) of the vegetable compartment 20 and a vegetable compartment return air passage 37 also flows into the return port 28 .

A defrosting heater 46 is provided below the cooler 45 as defrosting means for melting and removing frost adhering to the cooler 45 . The defrost heater 46 is an electric resistance heater.

At the top of the cooling chamber 26, a blower port 27, which is an opening leading to each storage chamber, is formed. Air blow port 27 is an opening through which cold air cooled by cooler 45 flows, and communicates cooling chamber 26 with refrigerating compartment supply air passage 29 and freezer compartment supply air passage 31 . A blower 47 is arranged in the blower port 27 to send out cool air from the front toward the freezer compartment 17 and the like.

Outside the blower port 27 of the cooling chamber 26 , a shielding device 70 is provided for appropriately blocking the air path leading from the blower port 27 . The shielding device 70 is covered with a front cover 67 from the front.

Here, although not shown in FIG. 3, a damper may be interposed in the refrigerating compartment supply air passage 29 . By doing so, the shielding device 70 and the damper can suitably blow cold air to each storage compartment.

With reference to FIG. 4, a configuration in which the shielding device 70 for regulating the airflow path described above is assembled will be described. 4A is a rear perspective view of the partition 66 to which the shielding device 70 is assembled, and FIG. 4B is a front perspective view of the partition 66. FIG.

4(A) and 4(B), the partition 66 is formed with a circular air blowing port 27 penetrating in the thickness direction in the upper portion thereof, and a blower is provided in front of the air blowing port 27. 47 and a shielding device 70 are provided. Here, the shielding device 70 is hidden behind the partition 66 in FIG. 4(A). An opening 59 formed on the upper end side of the partition 66 communicates with the refrigerating compartment supply air passage 29 shown in FIG.

5 is an exploded perspective view showing the front cover 67, the shielding device 70 and the partition 66. FIG. The shielding device 70 is arranged between the front cover 67 and the partition 66 . The shielding device 70 is composed of a lid member 57 , a rotating plate 73 and a support base 63 . The lid member 57 is a member that closes the rotary plate 73 from the front, and has a substantially circular shape when viewed from the front. The rotating plate 73 is a substantially disc-shaped member that rotates to open and close the shielding device 70 , and is rotatably attached to the support base 63 . The supporting base 63 is made of a synthetic resin plate molded into a predetermined shape, and each member constituting the shielding device 70 is attached. Also, the support base 63 is fitted into an opening 35 formed in the upper portion of the front cover 67 .

FIG. 6(A) is a sectional view taken along the section line AA in FIG. 4(A). As described above, the freezer compartment supply air passage 31 is formed as a space surrounded by the partition 66 and the front cover 67 . The freezer compartment supply air passage 31 is divided into a plurality of air passages as described later. A shielding device 70 and a shielding wall driving mechanism 60 are arranged between the partition 66 and the front cover 67 . The shielding device 70 shields the blower 47 , and the shielding wall driving mechanism 60 drives the shielding device 70 . The configurations of the shielding device 70 and the shielding wall driving mechanism 60 will be described later with reference to FIG. 7 and the like.

FIG. 6B is a plan view of the partition 66 viewed from the front. The partition 66 is formed with outlets 341 to 346 as the outlets 34 described above. A blowout port 341 and a blowout port 342 are formed at the upper end of the partition 66 . The outlet 343 and the outlet 344 are formed in the center of the partition 66 in the vertical direction. A blowout port 345 and a blowout port 346 are formed at the lower end of the partition 66 .

Further, the partition 66 is formed with a rib-shaped air passage partition wall 56 extending forward. A front end of the air passage partition wall 56 is in contact with the front cover 67 . The air passage partition wall 56 subdivides the freezer compartment supply air passage 31 into a plurality of air passages.

The configuration of the shielding device 70 will be described with reference to FIG. 7A is an exploded perspective view of the shielding device 70, and FIG. 7B is a perspective view showing the cam 61. FIG.

Referring to FIG. 7A, shielding device 70 includes support base 63 , rotating plate 73 , lid member 57 , and shielding wall drive mechanism 60 .

The shielding device 70 is a device that shields the air path of the cool air blown by the blower 47 . By opening the shielding device 70, air passages connecting the cooling chamber 26 and each storage chamber are communicated, and by closing the shielding device 70, the air passages are blocked.

The blower 47 is arranged at the center of the rear surface of the support base 63 via fastening means such as screws. The blower 47 includes, for example, a centrifugal fan such as a turbo fan and a blower motor that rotates the centrifugal fan, and blows cool air radially outward.

The rotation shielding wall 71 is a rectangular plate-like member made of synthetic resin, and has a long side along the tangential direction of the outer edge of the rotation plate 73 . The turn shielding wall 71 is attached near the periphery of the support base 63 so as to be able to turn rearward. A plurality (four in this embodiment) of the rotating shielding walls 71 are provided. The rotating shielding wall 71 is arranged in a path through which cold air blown by the blower 47 flows, and appropriately shields the air passage.

A frame-shaped portion 83 that surrounds the rotation shielding wall 71 in the upright state is adjacent to the base end portion that is the center of rotation of the rotation shielding wall 71 . The frame-shaped portion 83 is made of a frame-shaped synthetic resin and is arranged on the rear surface of the support base 63 so as to surround the blower 47 . The frame-shaped portion 83 is arranged corresponding to each rotation shielding wall 71, and the opening of the frame-shaped portion 83 is closed by the rotation shielding wall 71, thereby closing the air passage.

The rotary plate 73 has a substantially disk-like shape when viewed from the rear, and is rotatably arranged on the front side of the support base 63 . A slide groove 80 for rotating the rotation shielding wall 71 is formed in the rotation plate 73 . The slide groove 80 is formed on the rear surface of the rotary plate 73 as a bottomed groove surrounded by ribs. A gear groove 49 for transmitting torque is formed in the periphery of the rotary plate 73 . As will be described later, by driving the drive motor and rotating the rotating plate 73, the rotating shielding wall 71 opens and closes.

The lid member 57 is a plate-like member that covers the rotary plate 73 from the front, is formed slightly larger than the rotary plate 73, and has a substantially circular shape when viewed from the front.

The shielding wall driving mechanism 60 that opens and closes the rotating shielding wall 71 has a rotating plate 73, a cam 61, and a drive motor 74 (see FIG. 10A) that rotates the rotating plate 73. .

Referring to FIG. 7B, cam 61 is a flat rectangular parallelepiped member made of synthetic resin. The left end of the cam 61 protrudes rearward to form the rotary connecting portion 48 . A hole through which a later-described pin 69 can be inserted is formed in the rotary connecting portion 48 . Further, a moving shaft 76 projecting in a substantially cylindrical shape is formed from the front surface of the cam 61 on the right end side. The moving shaft 76 engages with the slide groove 80 of the rotary plate 73 and slides along the slide groove 80 under the condition of use. To enable this sliding, the diameter of the moving shaft 76 is set to be about the same as or slightly shorter than the radial width of the slide groove 80 .

Referring to FIG. 8, related configurations of the rotation blocking wall 71, the support base 63 and the cam 61 will be described. FIG. 8(A) is an exploded perspective view of the turning shielding wall 71, the support base 63 and the cam 61 as viewed from the rear left side, and FIG. 1 is an exploded perspective view as seen; FIG.

With reference to FIG. 8(A), the rotation shielding wall 71 is formed with a rotation connecting portion 68 projecting obliquely from the base end portion of the rotation shielding wall 71 . A hole through which the pin 69 can be inserted is formed in the rotary connecting portion 68 . In addition, rotary connecting portions 64 projecting in a substantially cylindrical shape are formed at the front end portions of both upper and lower side surfaces of the rotary shielding wall 71 . The rotary connecting portion 64 is inserted into a cylindrical concave portion 85 formed on the inner wall of the frame portion 83 . With such a configuration, the rotatable shielding wall 71 is provided on the support base 63 in a rotatable state.

A through-hole 86 is formed by passing through the support base 63 in a rectangular shape. The rotary connection portion 68 of the rotary shielding wall 71 is inserted into the through hole 86 from behind. The rotary connecting portion 48 of the cam 61 is also inserted into the through hole 86 from the front. A pin 69 is inserted into the hole of the rotary connecting portion 68 of the rotary blocking wall 71 and the hole of the rotary connecting portion 48 of the cam 61 . With such a configuration, the rotation blocking wall 71 and the cam 61 are rotatably connected with the support base 63 interposed therebetween.

Referring to FIG. 8B, a cam housing portion 62 is formed on the front surface of the support base 63 . The cam accommodating portion 62 is a rectangular area surrounded by ribs, and the above-described through hole 86 is formed inside the cam accommodating portion 62 . The cam 61 is housed inside the cam housing portion 62 and slides. The direction in which the cam 61 slides inside the cam accommodating portion 62 is the lateral direction here, in other words, the radial direction of the rotary plate 73 shown in FIG. 7(A).

With the configuration as described above, the drive motor 74 is driven to rotate the rotary plate 73 , so that the moving shaft 76 slides in the slide groove 80 . As a result, the cam 61 slides inside the cam housing portion 62 . By sliding the cam 61 , the rotation blocking wall 71 can be rotated around the pin 69 . Specifically, when the cam 61 is slid toward the peripheral edge of the rotary plate 73, the rotation shielding wall 71 rotates around the rotation connecting portion 64 so as to stand up, thereby shielding the rotation. The wall 71 is perpendicular to the main surface of the support base 63 . On the other hand, when the cam 61 is slid toward the center of the rotating plate 73, the rotation shielding wall 71 rotates around the rotation connecting portion 64 so as to be in a lying state, and the rotation shielding wall 71 is supported. It is in a state of being substantially parallel to the main surface of the base 63 .

Therefore, by forming the slide groove 80 on the peripheral edge side of the rotary plate 73, the rotation blocking wall 71 can be closed. On the contrary, if the slide groove 80 is formed on the center side of the rotating plate 73, the rotation shielding wall 71 can be opened. If the shape of the slide groove 80 is selected using this principle, the opening/closing state of the rotation shielding wall 71 can be arbitrarily set. As a result, the rotation shielding wall 71 can be fully opened or fully closed without adopting a complicated configuration.

FIG. 9A is a diagram showing the rotating shielding wall 711 and the like of the shielding device 70 as viewed from the rear. The shielding device 70 has a rotating shielding wall 711 to a rotating shielding wall 714 as the rotating shielding wall 71 described above. The rotation shielding wall 711 to rotation shielding wall 714 have a rectangular shape having long sides substantially parallel to the tangential direction of the rotation plate 73 described above. Also, the rotation shielding wall 711 to the rotation shielding wall 714 are rotatably attached to the peripheral portion of the support base 63 shown in FIG. 7(A).

A proximal end portion of the rotation shielding wall 711 is rotatably connected to a cam 611 having a movement shaft 761 formed thereon. Similarly, the radially inner end of the rotation blocking wall 712 is rotatably connected to a cam 612 having a movement shaft 762 formed thereon. A radially inner end portion of the rotation shielding wall 713 is rotatably connected to a cam 613 on which a movement shaft 763 is formed. Also, the radially inner end of the rotation shielding wall 714 is rotatably connected to a cam 614 on which a movement shaft 764 is formed.

Here, the direction in which the cam 611 slides is orthogonal to the longitudinal direction of the rotation blocking wall 711 . By doing so, it is possible to shorten the distance that the cam 611 should slide when opening and closing the rotation shielding wall 711 . Such a configuration is the same for other rotating shielding walls 712 and the like.

Referring to FIG. 9B, the rotating plate 73 is a steel plate or a synthetic resin plate molded into a substantially disc shape, and has a slide groove 80 for controlling the opening/closing operation of the above-described rotation shielding wall 711 and the like. formed.

A gear groove 49 is formed in most of the peripheral portion of the rotating plate 73, and the gear groove 49 meshes with the gear 30 described later with reference to FIG. The rotary plate 73 is rotated by the torque of the drive motor 74 shown in . Also, the gear groove 49 may be formed over the entire circumference of the rotary plate 73 , but here the gear groove 49 is not formed in a part of the outer circumference of the rotary plate 73 . That is, the gear groove 49 has both ends. Since the gear groove 49 has an end portion, the gear 30 (to be described later) rotates to the end portion of the gear groove 49, so that the position of the rotating plate 73 in the rotation direction can be easily detected.

The slide groove 80 is formed in a substantially annular shape near the outer peripheral edge of the rotary plate 73 . Furthermore, the shape of the slide groove 80 when the rotary plate 73 is viewed from behind is not a perfect circle, but a meandering shape that meanders along the circumferential direction of the rotary plate 73 . Specifically, slide groove 80 consists of slide grooves 801, 802, 803, 804, 805, 806, 807, 808, 8010, 8011 and slide groove 8012 along the clockwise direction. The slide groove 801 curves radially outward along the clockwise direction. The slide groove 802 extends substantially parallel to the circumferential direction. The slide groove 803 curves radially inward along the clockwise direction. The slide groove 804 curves radially outward along the clockwise direction. The slide groove 805 curves radially inward along the clockwise direction. The slide groove 806 curves radially outward along the clockwise direction. The slide groove 807 curves radially inward along the clockwise direction. The slide groove 808 curves radially outward along the clockwise direction. The slide groove 809 curves radially inward along the clockwise direction. The slide groove 8010 curves radially outward along the clockwise direction. The slide groove 8011 extends substantially parallel to the circumferential direction. The slide groove 8012 curves radially inward along the clockwise direction.

In the slide groove 80, a change point is set at which the curved shape of the groove changes. Specifically, a change point 812 is set between the slide grooves 801 and 802 , and a change point 813 is set between the slide grooves 802 and 803 . A change point 814 is set between the slide grooves 803 and 804 , and a change point 815 is set between the slide grooves 804 and 805 . A change point 816 is set between the slide grooves 805 and 806 , and a change point 817 is set between the slide grooves 806 and 807 . A change point 818 is set between the slide grooves 807 and 808 , and a change point 819 is set between the slide grooves 808 and 809 . A change point 8110 is set between the slide grooves 809 and 8010 , and a change point 8111 is set between the slide grooves 8010 and 8011 . A change point 8112 is set between the slide grooves 8011 and 8012 , and a change point 811 is set between the slide grooves 8012 and 801 .

The change point 812 , the change point 813 , the change point 815 , the change point 817 , the change point 819 , the change point 8111 and the change point 812 described above are arranged radially outside the rotary plate 73 . On the other hand, the change point 811 , the change point 814 , the change point 816 , the change point 818 and the change point 8110 are arranged radially inside the rotary plate 73 .

FIG. 10 shows the configuration of the shielding device 70 in the fully closed state. 10(A) is a rear view of the shielding device 70 in the fully closed state, FIG. 10(B) is a rear view of the rotary plate 73 and the like in the fully closed state, and FIG. 10(C). is a cutaway perspective view of the shielding device 70 in a fully closed state.

Referring to FIG. 10A, shielding device 70 prevents air from flowing out of blower 47 to the outside in the fully closed state. In other words, in the fully closed state, all of the rotating shielding walls 711 to 714, which are the shielding devices 70, are in an upright state. Therefore, communication with the air passage for supplying cold air is cut off, and cold air is not supplied to the freezer compartment 17 described above. Also, during the defrosting process of defrosting the cooler 45 shown in FIG.

Referring to FIG. 10B, when the shielding device 70 is brought into the fully closed state, first, the rotating plate 73 is rotated via the gear 30 by driving the drive motor 74 shown in FIG. Let Here, by rotating the rotary plate 73, the moving shaft 761 and the like slide in the slide groove 80 and move radially outward. Specifically, the movement shaft 761 is arranged at the transition point 813 of the slide groove 80 and the movement shaft 762 is arranged at the transition point 815 of the slide groove 80 . Further, the moving shaft 763 is arranged at the transition point 817 of the slide groove 80 and the movement shaft 764 is arranged at the transition point 819 of the slide groove 80 .

Referring to FIG. 10C, as a result, cam 611 moves radially outward. The rotation shielding wall 711 rotatably connected to the cam 611 rotates around the vicinity of the rotation connecting portion 68 as a rotation center, and stands substantially perpendicular to the main surface of the support base 63 in a closed state. becomes. As a result, the opening of the frame-shaped portion 83 is closed by the rotation shielding wall 711, and the air passage is shielded. Such a configuration is the same for other turning shielding walls 712 and the like.

FIG. 11 shows the construction of the shielding device 70 in the fully open state. 11A is a rear view of the shielding device 70 in the fully open state, FIG. 11B is a rear view of the rotary plate 73 and the like in the fully open state, and FIG. Fig. 2 is a perspective cut-away view of the shielding device 70 in a state;

Referring to FIG. 11(A), shielding device 70 does not block the flow of air from blower 47 to the outside in the fully open state. In the fully open state, all the turning shielding walls 711 and the like are open toward the surroundings. That is, in the fully open state, cold air blown from the blower 47 to the shielding device 70 is blown to the refrigerator compartment 15 and the freezer compartment 17 without being interfered by the rotating shielding wall 71 .

Referring to FIG. 11B, when the shielding device 70 is to be fully opened, first, the drive motor 74 shown in FIG. 10A is driven to rotate the rotary plate 73 via the gear 30. . Here, by rotating the rotating plate 73, the moving shaft 761 and the like slide in the slide groove 80 and move radially inward. Specifically, the moving shaft 761 is arranged at the transition point 814 of the slide groove 80 , and the movement shaft 762 is arranged at the transition point 816 of the slide groove 80 . Further, the moving shaft 763 is arranged at the transition point 818 of the slide groove 80 and the movement shaft 764 is arranged at the transition point 8110 of the slide groove 80 .

Referring to FIG. 11C, as a result, cam 611 moves radially inward. The rotation shielding wall 711 rotatably connected to the cam 611 rotates about the vicinity of the rotation connecting portion 68 as a rotation center, and is in an open state in which it falls substantially parallel to the main surface of the support base 63 . becomes. As a result, the opening of the frame-shaped portion 83 is not blocked by the rotating shielding wall 711, the flow path resistance of the air path can be reduced, and the amount of air blown by the blower 47 can be increased. Such a configuration is the same for other turning shielding walls 712 and the like.

In the present embodiment, referring to FIG. 7, the rotating shielding wall 71 is opened and closed by the rotation of the rotating plate 73. Therefore, the shielding device 70 can be made thinner than the background art described above. can do. Therefore, referring to FIG. 2, the volume of the freezer compartment 17 formed in front of the shielding device 70 can be increased.

Furthermore, according to this embodiment, as shown in FIG. are combined. By rotating the rotating plate 73 , the moving shafts 762 to 764 slide along the slide grooves 80 and slide along the radial direction of the rotating plate 73 . When the moving shafts 762 through 764 slide, the cams 611 through 614 also slide, and as a result, the rotation shielding walls 711 through 714 are opened and closed.

Therefore, since a plurality of moving shafts 761 to 764 are engaged and slid in one slide groove 80, the distance of the slide groove 80 in which the moving shafts 761 to 764 can slide can be increased. . Therefore, the slide groove 80 can be smoothly bent along the circumferential direction, and the pressure generated when the moving shafts 761 to 764 slide along the slide groove 80 is reduced, and the opening and closing operation of the rotation shielding wall 711 is performed. can be done smoothly.

12 to 35, by rotating the rotating plate 73 of the shielding device 70 clockwise in increments of 30 degrees, the rotating shielding wall 711 to the rotating shielding wall 714 are opened and closed, thereby opening and closing the air passage. The operation of opening/closing and switching will be described. In the following description, the radial and circumferential directions of rotating plate 73 are simply referred to as radial and circumferential directions. Furthermore, in the following description, by rotating the rotary plate 73 clockwise in increments of 30 degrees, the open/closed state of the rotary shielding wall 711 and the like is changed from pattern 1 to pattern 12 . That is, in the present embodiment, the rotation shielding wall 711 to the rotation shielding wall 714 are controlled to open and close by rotating the rotation plate 73 in units of 30 degrees with the layout angle of the rotation plate 73 set to 30 degrees. Here, the allocation angle is a divisor of 360 degrees, and may be 60 degrees or 120 degrees, for example.

12 and 13 show pattern 1 in which all the turning shielding walls 71 and the like are in the open state. FIG. 12(A) is a rear view of the shielding device 70 in this state, FIG. 12(B) is a rear view of the rotary plate 73 in this state, and FIG. It is the figure which looked at the condition of the air course in a state from the back.

Referring to FIG. 12A, in pattern 1, all of the rotation shielding walls 711 to 714 are in the open state. Such an open/closed state allows blower 47 to blow cold air to refrigerator compartment 15 and freezer compartment 17 .

Referring to FIG. 12(B), in this state, the moving shaft 761 and the like are arranged radially inward. Specifically, the moving shaft 761 is arranged at the transition point 814 of the slide groove 80 , and the movement shaft 762 is arranged at the transition point 816 of the slide groove 80 . Further, the moving shaft 763 is arranged at the transition point 818 of the slide groove 80 and the movement shaft 764 is arranged at the transition point 8110 of the slide groove 80 . As a result, the rotation shielding wall 711 to the rotation shielding wall 714 are opened.

Referring to FIG. 13, when shielding device 70 is in the state shown in FIG. Cold air is blown out from the outlet 346 to the entire freezer compartment 17 .

14 and 15 show pattern 2 in which all the turning shielding walls 711 and the like are closed. Pattern 2 is a state in which the rotation plate 73 is rotated clockwise by 30 degrees from pattern 1 . 14(A) is a rear view of the shielding device 70 in this state, FIG. 14(B) is a rear view of the rotary plate 73 in this state, and FIG. It is the figure which looked at the condition of the air course in this state from the back.

Referring to FIG. 14A, in pattern 2, all of rotation shielding wall 711 to rotation shielding wall 714 are closed. With such an open/closed state, the blower 47 can block the blowing of air to the freezer compartment 17 . Also, warm air can be prevented from entering the freezer compartment 17 during defrosting.

Referring to FIG. 14B, in this state, the moving shaft 761 and the like are arranged radially outward. Specifically, the movement shaft 761 is arranged at the transition point 813 of the slide groove 80 and the movement shaft 762 is arranged at the transition point 815 of the slide groove 80 . Further, the moving shaft 763 is arranged at the transition point 817 of the slide groove 80 and the movement shaft 764 is arranged at the transition point 819 of the slide groove 80 . As a result, all of the rotation shielding walls 711 to 714 are closed.

Referring to FIG. 15, when shielding device 70 is in the state shown in FIG. Cold air is not blown out from the outlet 346 to the entire freezer compartment 17 .

FIGS. 16 and 17 show pattern 3 in which only the right turn shielding wall 711 is closed. Pattern 3 is a state in which the rotation plate 73 is rotated 30 degrees clockwise from pattern 2 . FIG. 16(A) is a rear view of the shielding device 70 in this state, FIG. 16(B) is a rear view of the rotary plate 73 in this state, and FIG. It is the figure which looked at the condition of the air course in a state from the back.

16A, in pattern 3, rotation shielding wall 711 is closed, and rotation shielding wall 712, rotation shielding wall 713, and rotation shielding wall 714 are open. By adopting such an open/closed state, it is possible to partially block the blowing of air to the freezer compartment 17 by the blower 47 .

Referring to FIG. 16B, in this state, moving shaft 761 is arranged radially outward, and moving shaft 762, moving shaft 763 and moving shaft 764 are arranged radially inside. Specifically, the moving shaft 761 is arranged at the transition point 812 of the slide groove 80 , and the movement shaft 762 is arranged at the transition point 814 of the slide groove 80 . The moving shaft 763 is arranged at the changing point 816 of the slide groove 80 and the moving shaft 764 is arranged at the changing point 818 of the slide groove 80 . As a result, the rotation shielding wall 711 is closed, and the rotation shielding wall 712, the rotation shielding wall 713, and the rotation shielding wall 714 are opened.

17, when shielding device 70 is in the state shown in FIG. 16, rotating shielding wall 711 blocks cold air, while rotating shielding wall 712, rotating shielding wall 713, and rotating shielding wall 714 block cold air. do not block Therefore, the cold air is blown leftward and downward, and specifically, after being blown toward the outlets 341 , 343 , 344 , 345 , and 346 , the cold air is is blown out.

18 and 19 show pattern 4 in which only the turning shielding wall 711 arranged on the right side is in the open state. Pattern 4 is a state in which the rotation plate 73 is rotated 30 degrees clockwise from pattern 3 . FIG. 18(A) is a rear view of the shielding device 70 in this state, FIG. 18(B) is a rear view of the rotary plate 73 in this state, and FIG. It is the figure which looked at the condition of the air course in a state from the back.

18A, in pattern 4, rotation shielding wall 711 is open, and rotation shielding wall 712, rotation shielding wall 713, and rotation shielding wall 714 are closed. By adopting such an open/closed state, it is possible to limit the blowing of air to the freezer compartment 17 by the blower 47 only to the right side.

Referring to FIG. 18B, in this state, moving shaft 761 is arranged radially inward, and moving shafts 762, 763 and 764 are arranged radially outward. Specifically, the moving shaft 761 is arranged at the transition point 811 of the slide groove 80 , and the movement shaft 762 is arranged at the transition point 813 of the slide groove 80 . Further, the moving shaft 763 is arranged at the transition point 815 of the slide groove 80 and the movement shaft 764 is arranged at the transition point 817 of the slide groove 80 . As a result, the rotation shielding wall 711 is opened, and the rotation shielding wall 712, the rotation shielding wall 713, and the rotation shielding wall 714 are closed.

19, when shielding device 70 is in the state shown in FIG. 18, rotating shielding wall 711 does not block cold air, while rotating shielding wall 712, rotating shielding wall 713, and rotating shielding wall 714 do not block cold air. keep out the cold. Therefore, the cold air is blown rightward, specifically, after being blown toward the outlet 342 , it is blown out into the freezer compartment 17 .

20 and 21 show pattern 5 in which the turning shielding wall 711 and the like arranged on the right side are closed. Pattern 5 is a state in which the rotary plate 73 is rotated 30 degrees clockwise from pattern 4 . FIG. 20(A) is a rear view of the shielding device 70 in this state, FIG. 20(B) is a rear view of the rotary plate 73 in this state, and FIG. It is the figure which looked at the condition of the air course in a state from the back.

20A, in pattern 5, rotation shielding wall 711 and rotation shielding wall 712 are closed, and rotation shielding wall 713 and rotation shielding wall 714 are open. With such an open/closed state, the blower 47 can blow cool air to the left portion of the freezer compartment 17 .

Referring to FIG. 20B, in this state, movement shafts 761 and 762 are arranged radially outward, and movement shafts 763 and 764 are arranged radially inward. Specifically, the moving shaft 761 is arranged at the transition point 8112 of the slide groove 80 , and the movement shaft 762 is arranged at the transition point 812 of the slide groove 80 . Further, the moving shaft 763 is arranged at the changing point 814 of the slide groove 80 and the moving shaft 764 is arranged at the changing point 816 of the slide groove 80 . As a result, the rotation shielding wall 711 and the rotation shielding wall 712 are closed, and the rotation shielding wall 713 and the rotation shielding wall 714 are opened.

21, when shielding device 70 is in the state shown in FIG. 20, rotating shielding wall 711 and rotating shielding wall 712 block cold air, while rotating shielding wall 713 and rotating shielding wall 714 block cold air. do not block Therefore, the cool air is blown leftward, and more specifically, is blown out into the freezer compartment 17 after being blown toward the outlets 341 , 343 and 345 .

22 and 23 show pattern 6 in which only the turning shielding wall 712 arranged on the right side is in the open state. Pattern 6 is a state in which the rotary plate 73 is rotated 30 degrees clockwise from pattern 5 . FIG. 22(A) is a rear view of the shielding device 70 in this state, FIG. 22(B) is a rear view of the rotary plate 73 in this state, and FIG. It is the figure which looked at the condition of the air course in this state from the back.

22A, in pattern 6, rotation shielding wall 711, rotation shielding wall 713, and rotation shielding wall 714 are closed, and only rotation shielding wall 712 is open. . With such an open/closed state, the blower 47 can blow cool air to the lower right portion of the freezer compartment 17 .

Referring to FIG. 22B, in this state, movement shafts 761, 763 and 764 are arranged radially outward, and movement shaft 762 is arranged radially inward. Specifically, the moving shaft 761 is arranged at the transition point 8111 of the slide groove 80 , and the movement shaft 762 is arranged at the transition point 811 of the slide groove 80 . Further, the moving shaft 763 is arranged at the transition point 813 of the slide groove 80 and the movement shaft 764 is arranged at the transition point 815 of the slide groove 80 . As a result, only the rotation shielding wall 712 is opened, and the rotation shielding wall 711, the rotation shielding wall 713, and the rotation shielding wall 714 are closed.

Referring to FIG. 23, when shielding device 70 is in pattern 6, rotating shielding wall 711, rotating shielding wall 713, and rotating shielding wall 714 shield cold air, while rotating shielding wall 712 does not shield cold air. Therefore, the cold air is blown downward on the right side, and more specifically, is blown out into the freezer compartment 17 after being blown toward the blower outlets 344 and 346 .

FIGS. 24 and 25 show pattern 7 in which the upper turn shielding wall 711 and turn shielding wall 714 are in the open state. Pattern 7 is obtained by rotating the rotation plate 73 clockwise from pattern 6 by 30 degrees. FIG. 24(A) is a rear view of the shielding device 70 in this state, FIG. 24(B) is a rear view of the rotary plate 73 in this state, and FIG. It is the figure which looked at the condition of the air course in a state from the back.

Referring to FIG. 24A, in pattern 7, rotation shielding wall 711 and rotation shielding wall 714 are in the open state, and rotation shielding wall 712 and rotation shielding wall 713 are in the closed state. With such an open/closed state, the air blower 47 can blow cool air to the upper portion of the freezer compartment 17 .

Referring to FIG. 24B, in this state, movement shafts 761 and 764 are arranged radially inward, and movement shafts 762 and 763 are arranged radially outward. Specifically, the moving shaft 761 is arranged at the transition point 8110 of the slide groove 80 , and the movement shaft 762 is arranged at the transition point 8112 of the slide groove 80 . Further, the moving shaft 763 is arranged at the transition point 812 of the slide groove 80 and the movement shaft 764 is arranged at the transition point 814 of the slide groove 80 . As a result, the rotation shielding wall 711 and the rotation shielding wall 714 are opened, and the rotation shielding wall 712 and the rotation shielding wall 713 are closed.

25, when shielding device 70 is in pattern 7, rotating shielding wall 712 and rotating shielding wall 713 block cold air, while rotating shielding wall 711 and rotating shielding wall 714 do not block cold air. Therefore, the cool air is blown upward, and more specifically, is blown out into the freezer compartment 17 after being blown toward the blower outlets 341 and 342 .

26 and 27 show pattern 8 in which only the turning shielding wall 713 is opened. Pattern 8 is obtained by rotating the rotary plate 73 clockwise from pattern 7 by 30 degrees. FIG. 26(A) is a rear view of the shielding device 70 in this state, FIG. 26(B) is a rear view of the rotating plate 73 in this state, and FIG. It is the figure which looked at the condition of the air course in a state from the back.

26A, in pattern 8, only rotation shielding wall 713 is open, and rotation shielding wall 711, rotation shielding wall 712, and rotation shielding wall 714 are closed. By setting the open/closed state, the blower 47 can blow cold air to the lower left side of the freezer compartment 17 .

Referring to FIG. 26B, in this state, movement shaft 763 is arranged radially inward, and movement shaft 761, movement shaft 762 and movement shaft 764 are arranged radially outward. Specifically, the moving shaft 761 is arranged at the transition point 819 of the slide groove 80 , and the movement shaft 762 is arranged at the transition point 8111 of the slide groove 80 . Further, the moving shaft 763 is arranged at the changing point 811 of the slide groove 80 and the moving shaft 764 is arranged at the changing point 813 of the slide groove 80 . As a result, the rotation shielding wall 713 is opened, and the rotation shielding wall 711, the rotation shielding wall 712, and the rotation shielding wall 714 are closed.

27, when shielding device 70 is in pattern 8, rotating shielding wall 711, rotating shielding wall 712, and rotating shielding wall 714 block cold air, while rotating shielding wall 713 does not block cold air. Therefore, the cold air is blown downward to the left side, and more specifically, is blown out to the freezer compartment 17 after being blown toward the blower outlets 343 and 345 .

28 and 29 show pattern 9 in which only the rotation shielding wall 711 and the rotation shielding wall 712 are opened. Pattern 9 is obtained by rotating the rotary plate 73 clockwise from pattern 8 by 30 degrees. FIG. 28(A) is a rear view of the shielding device 70 in this state, FIG. 28(B) is a rear view of the rotary plate 73 in this state, and FIG. It is the figure which looked at the condition of the air course in a state from the back.

Referring to FIG. 28A, in pattern 9, rotation shielding wall 711 and rotation shielding wall 712 are in the open state, and rotation shielding wall 713 and rotation shielding wall 714 are in the closed state. With such an open/closed state, the blower 47 can blow cold air to the right portion of the freezer compartment 17 .

Referring to FIG. 28B, in this state, movement shafts 761 and 762 are arranged radially inward, and movement shafts 763 and 764 are arranged radially outward. Specifically, the movement shaft 761 is arranged at the transition point 818 of the slide groove 80 and the movement shaft 762 is arranged at the transition point 8110 of the slide groove 80 . Further, the moving shaft 763 is arranged at the changing point 8112 of the slide groove 80 and the moving shaft 764 is arranged at the changing point 812 of the slide groove 80 . As a result, the rotation shielding wall 711 and the rotation shielding wall 712 are opened, and the rotation shielding wall 713 and the rotation shielding wall 714 are closed.

29, when shielding device 70 is in pattern 9, rotating shielding wall 711 and rotating shielding wall 712 do not block cold air, while rotating shielding wall 713 and rotating shielding wall 714 block cold air. Therefore, the cold air is blown rightward, and more specifically, is blown out into the freezer compartment 17 after being blown through the blower outlets 342 , 344 and 346 .

30 and 31 show the pattern 10 in which only the rotating shielding wall 714 is opened. Pattern 10 is obtained by rotating the rotary plate 73 clockwise from pattern 9 by 30 degrees. FIG. 30(A) is a rear view of the shielding device 70 in this state, FIG. 30(B) is a rear view of the rotary plate 73 in this state, and FIG. It is the figure which looked at the condition of the air course in a state from the back.

30A, in pattern 10, rotation shielding wall 711, rotation shielding wall 712, and rotation shielding wall 713 are closed, and rotation shielding wall 714 is open. In this open/closed state, the blower 47 can blow cool air to the upper left portion of the freezer compartment 17 .

Referring to FIG. 30B, in this state, movement shafts 761, 762 and 763 are arranged radially outward, and movement shaft 764 is arranged radially inward. Specifically, the movement shaft 761 is arranged at the transition point 817 of the slide groove 80 and the movement shaft 762 is arranged at the transition point 819 of the slide groove 80 . Further, the moving shaft 763 is arranged at the changing point 8111 of the slide groove 80 and the moving shaft 764 is arranged at the changing point 811 of the slide groove 80 . As a result, the rotation shielding wall 711, the rotation shielding wall 712, and the rotation shielding wall 713 are closed, and the rotation shielding wall 714 is opened.

31, when shielding device 70 is in pattern 10, rotating shielding wall 711, rotating shielding wall 712, and rotating shielding wall 713 block cold air, while rotating shielding wall 714 does not block cold air. Therefore, the cold air is blown upward to the left, and more specifically, is blown to the freezer compartment 17 after being blown to the outlet 341 .

32 and 33 show the pattern 11 in which only the turning shielding wall 714 is closed. The pattern 11 is obtained by rotating the rotary plate 73 clockwise from the pattern 10 by 30 degrees. FIG. 32(A) is a rear view of the shielding device 70 in this state, FIG. 32(B) is a rear view of the rotary plate 73 in this state, and FIG. It is the figure which looked at the condition of the air course in a state from the back.

32A, in pattern 11, rotation shielding wall 711, rotation shielding wall 712, and rotation shielding wall 713 are opened, and rotation shielding wall 714 is closed. In such an open/closed state, blower 47 can blow cool air to the right and lower portions of freezer compartment 17 .

Referring to FIG. 32B, in this state, movement shafts 761, 762 and 763 are arranged radially inward, and movement shaft 764 is arranged radially outward. Specifically, the moving shaft 761 is arranged at the transition point 816 of the slide groove 80 and the movement shaft 762 is arranged at the transition point 818 of the slide groove 80 . Further, the moving shaft 763 is arranged at the transition point 8110 of the slide groove 80 and the movement shaft 764 is arranged at the transition point 8112 of the slide groove 80 . As a result, the rotation shielding wall 711, the rotation shielding wall 712, and the rotation shielding wall 713 are opened, and the rotation shielding wall 714 is closed.

33, when shielding device 70 is in pattern 11, rotating shielding wall 711, rotating shielding wall 712, and rotating shielding wall 713 do not block cold air, while rotating shielding wall 714 blocks cold air. Therefore, the cold air is blown rightward and downward, and more specifically, is blown out into the freezer compartment 17 after being blown through the blower outlets 342 , 344 , 346 and 345 .

34 and 35 show the pattern 12 in which all the turning shielding walls 714 and the like are closed. The pattern 12 is obtained by rotating the rotary plate 73 clockwise from the pattern 11 by 30 degrees. FIG. 34(A) is a rear view of the shielding device 70 in this state, FIG. 34(B) is a rear view of the rotary plate 73 in this state, and FIG. It is the figure which looked at the condition of the air course in a state from the back.

34A, in pattern 12, rotation shielding wall 711, rotation shielding wall 712, rotation shielding wall 713, and rotation shielding wall 714 are closed. Such an open/closed state closes the air blowing path from the air blower 47 and partitions the cooling chamber 26 and the freezing chamber 17 shown in FIG. 3 .

Referring to FIG. 34B, in this state, moving shaft 761, moving shaft 762, moving shaft 763 and moving shaft 764 are arranged radially outward. Specifically, the movement shaft 761 is arranged at the transition point 815 of the slide groove 80 and the movement shaft 762 is arranged at the transition point 817 of the slide groove 80 . Further, the moving shaft 763 is arranged at the changing point 819 of the slide groove 80 and the moving shaft 764 is arranged at the changing point 8111 of the slide groove 80 . As a result, the rotation shielding wall 711, the rotation shielding wall 712, the rotation shielding wall 713, and the rotation shielding wall 714 are closed.

35, when shielding device 70 is in pattern 11, rotating shielding wall 711, rotating shielding wall 712, rotating shielding wall 713, and rotating shielding wall 714 shield cold air. Therefore, cold air is not blown to the outlet 342 and the like.

The above is the description of the operation of the shielding device 70 .

According to the shielding device 70 of the present embodiment, various opening/closing patterns of the rotating shielding wall 711 to the rotating shielding wall 714 can be realized by a simple control operation of rotating the shielding device 70 by a predetermined angle. Specifically, 12 types of opening/closing patterns can be realized in units of 30 degrees. Therefore, it is possible to realize a large number of cold air blowing modes, and it is possible to suitably blow cold air according to the cooling state inside the freezer compartment 17 .

Further, as described above, since the movement shafts 761 and the like of the four rotation shielding walls 711 and the like are slid in one slide groove 80, the degree of bending of the slide groove 80 can be reduced. The sliding motion can be performed smoothly.

Furthermore, the sliding range of the slide groove 80 overlaps with the plurality of cams 611 and the like. Specifically, referring to FIG. 36, a first sliding range, which is a range in which a moving shaft 761 of cam 611 (first cam) slides in slide groove 80, and a movement range of cam 612 (second cam). The second sliding range, which is the range in which the shaft 762 slides in the slide groove 80, overlaps in the circumferential direction. That is, the rotating plate 73 rotates 330 degrees when shifting from pattern 1 to pattern 12 described above. Therefore, substantially the entire slide groove 80 is the first sliding range and the second sliding range. Therefore, substantially the entire slide groove 80 can be shared by a plurality of cams 611 and the like, and the configuration of the shielding device 70 can be simplified.

37(A) and 37(B) show a modification of the shielding device 70. FIG. FIGS. 37(A) and 37(B) are rear views of the shielding device 70 according to the modification. Here, slide grooves 8015 and 8016 are formed as the plurality of slide grooves 80 in the rotating plate 73 .

Referring to FIG. 37A, rotary plate 73 is formed with slide grooves 8015 and 8016, which are spaced apart in the circumferential direction. In other words, the moving shaft 764 and the moving shaft 763 are displaced in the circumferential direction. Further, the slide grooves 8015 and 8016 are formed meandering along the circumferential direction. Furthermore, the slide groove 8015 and the slide groove 8016 are formed in an incomplete ring shape. As a result, for example, by rotating the rotary plate 73 until the moving shaft 761 contacts the end of the slide groove 8016, the position of the rotary plate 73 in the rotational direction can be detected.

A moving shaft 764 and a moving shaft 763 are engaged with the slide groove 8015 . Also, the moving shaft 761 and the moving shaft 762 are engaged with the 8016 . Here, the movement shielding wall 711 and the rotation shielding wall 712 are closed by arranging the movement shaft 761 and the movement shaft 762 radially outward. Further, since the moving shaft 763 and the moving shaft 764 are radially inward, the rotation shielding wall 713 and the rotation shielding wall 714 are in an open state.

FIG. 37(B) shows a state in which the shielding device 70 is rotated counterclockwise by about 30 degrees from the state in FIG. 37(A). In this state, the movement shaft 761 and the movement shaft 762 are arranged radially inward, so that the rotation shielding wall 711 and the rotation shielding wall 712 are in an open state. In addition, since the movement shaft 763 and the movement shaft 764 are radially outward, the rotation shielding wall 713 and the rotation shielding wall 714 are closed.

Even in the modified example described above, two moving shafts 763 and 764 are engaged with one slide groove 8015 . Therefore, many opening/closing patterns of the rotating shielding wall 714 and the like can be realized. In addition, the degree of curvature of the slide groove 8015 can be moderated, and the sliding motion of the moving shafts 763 and 764 can be performed smoothly.

FIG. 38 shows a further variant of the shielding device 70. As shown in FIG. FIG. 38 is a rear view of a shielding device 70 according to a modification.

The shielding device 70 shown here has a pivoting shielding wall 715 . Rotating shielding wall 715 opens and closes the air path supplied to refrigerator compartment 15 described above. Cold air can be blown into the refrigerator compartment 15 by opening the rotating shielding wall 715 . On the other hand, by closing the rotating shielding wall 715 , cold air is not blown to the refrigerator compartment 15 . The rotation shielding wall 715 has the same configuration as the other rotation shielding wall 711 and is rotatably connected to the cam 615 . A moving shaft 765 is formed on the cam 615, and the moving shaft 765 is engaged with a slide groove 8018, which will be described later. With such a configuration, it is not necessary to interpose a damper in the refrigerating compartment supply air passage 29 shown in FIG. 2, and the overall configuration of the refrigerator 10 can be simplified.

A slide groove 8017 (first slide groove) and a slide groove 8018 (second slide groove) are formed in the rotary plate 73 . The slide grooves 8017 and 8018 are arranged with a radial shift. That is, the slide groove 8018 is formed inside the slide groove 8017 . Here, the inner slide groove 8017 is formed in an incomplete ring shape, and the outer slide groove 8018 is formed in a ring shape. The slide grooves 8017 and 8018 are meandering in the circumferential direction so as to slide the cam 611 and the like along the radial direction.

The moving shafts 761 to 764 are engaged with and slide in the slide grooves 8017 . A moving shaft 765 is engaged with and slides in the slide groove 8018 .

When the rotary plate 73 rotates under the condition of use, the movement shafts 761 through 764 slide along the slide grooves 8017, thereby opening and closing the rotation shielding walls 711 through 714. FIG. Further, the movement shielding wall 715 opens and closes by sliding the moving shaft 765 along the slide groove 8018 .

As described above, by forming a plurality of slide grooves 8017 and slide grooves 8018 in the rotary plate 73 and forming the slide grooves 8017 and 8018 by shifting them in the radial direction, more rotation shielding walls 711 and the like are formed. opening and closing control can be realized smoothly.

The present invention is not limited to the above embodiments, and various modifications can be made without departing from the scope of the present invention.

10 Refrigerator 11 Insulation box body 12 Outer box 13 Inner box 14 Insulation material 15 Refrigerator compartment 17 Freezer compartment 18 Upper freezer compartment 19 Lower freezer compartment 20 Vegetable compartment 21 Insulated door 23 Insulated door 24 Insulated door 25 Insulated door 26 Cooling compartment 27 Air outlet 28 return port 29 refrigerator compartment supply air passage 30 gear 31 freezer compartment supply air passage 33 air outlets 34, 341, 342, 343, 344, 345, 346 outlet 35 opening 37 vegetable compartment return air passage 38 return port 39 return port 42 Heat insulation partition wall 43 Heat insulation partition wall 44 Compressor 45 Cooler 46 Defrost heater 47 Blower 48 Rotating connection part 49 Gear groove 56 Air passage partition wall 57 Lid member 59 Opening part 60 Shield wall drive mechanism 61, 611, 612, 613, 614, 615, 616 Cam 62 Cam storage portion 63 Support base 64 Rotation connection portion 65 Partition 66 Partition 67 Front cover 68 Rotation connection portion 69 Pin 70 Shielding device 71, 711, 712, 713, 714, 715 Rotating shield wall
73 rotary plate 74 drive motors 76, 761, 762, 763, 764, 765 moving shaft 80 slide grooves 801, 802, 803, 804, 805, 806, 807, 808, 809, 8010, 8011, 8012, 8013, 8014, 8015, 8016, 8017, 8018 Slide grooves 811, 812, 813, 814, 815, 816, 817, 818, 819, 8110, 8111, 8112 Point of change 83 Frame-shaped portion 85 Recessed portion 86 Through hole 100 Refrigerator 101 Refrigerator compartment 102 Freezer compartment 103 Vegetable compartment 104 Cooling compartment 105 Partition wall 106 Opening 107 Blower fan 108 Cooler 109 Air passage 110 Blower cover 111 Recess 113 Opening 114 Damper

Claims (7)

A shielding device for blocking an air passage through which cold air is blown inside a refrigerator,
a plurality of rotating shielding walls surrounding the blower from the outside in the radial direction;
a shielding wall driving mechanism for driving the rotating shielding wall,
The shielding wall drive mechanism includes a rotating plate having a slide groove formed along the circumference, and a plurality of moving shafts formed to engage with the slide groove and rotatably connected to the rotating shielding wall. and a motor for rotating the rotating plate,
the moving shafts of the plurality of cams are engaged with one of the slide grooves;
A shielding device according to claim 1, wherein a plate-like support base is arranged between the rotating shielding wall and the shielding wall driving mechanism . The cam has a first cam and a second cam,
2. A first sliding range in which said first cam slides in said slide groove and a second sliding range in which said second cam slides in said slide groove overlap with each other. The shielding device according to . 3. A shielding device according to claim 1, wherein said slide groove is formed in an annular shape. 3. The shielding device according to claim 1, wherein the slide groove is formed in an incomplete ring shape. 5. The slide groove according to any one of claims 1 to 4, wherein the slide groove has a first slide groove and a second slide groove formed inside the first slide groove in the radial direction. The shielding device according to . The motor rotates the rotating plate through a gear meshing with a gear groove formed around the rotating plate,
6. The shielding device according to any one of claims 1 to 5, wherein the gear groove is not formed in a part of the periphery of the rotary plate. a refrigeration cycle cooler that cools the air supplied to the storage chamber via the air passage;
a cooling chamber in which the cooler is disposed and an air outlet leading to the storage chamber is formed;
the air blower that blows the air supplied from the air blow port toward the storage chamber;
A refrigerator, comprising: the shielding device according to any one of claims 1 to 6, which at least partially blocks the air passage.

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