JP6956886B2 - refrigerator - Google Patents

Description

The present invention relates to a refrigerator that suppresses malfunction of a damper device that opens and closes an air passage that supplies air to a storage chamber.

In recent years, worktop type refrigerators have become the mainstream in refrigerators having a plurality of storage chambers and having a rated internal volume of 300 L or more. In the worktop type refrigerator, the refrigerator compartment is arranged at the uppermost stage, and the other storage chambers are arranged below the refrigerator compartment. The opening on the front side of the refrigerator compartment can be opened and closed with, for example, a double door. In addition, other storage rooms can be opened and closed with, for example, a drawer-type door. Other storage rooms are, for example, an ice making room, a small freezing room, a freezing room, and a vegetable room. In addition, the trend is to increase the capacity of refrigerators so that all foods can be stored even during bulk purchases on weekends according to the lifestyle of the user.

In many refrigerators, the following configurations are adopted in order to keep each storage chamber of the refrigerator at a predetermined temperature. Specifically, the storage chamber is provided with a temperature sensor that detects the temperature in the storage chamber. Further, a damper device for opening and closing the air passage is provided in the air passage for supplying the cold air, which is the air cooled by the cooler, to the storage chamber. The damper device is formed with a part of an air passage that supplies cold air to the storage chamber. Further, the damper device includes a baffle that opens and closes the air passage, and a drive unit that operates the baffle by the driving force of the motor. Then, when the damper device closes the air passage that supplies cold air to the storage chamber, the baffle contacts the peripheral edge of the air passage in the damper device from above and closes the air passage.

In the refrigerator, the inside of the housing composed of the inner box and the outer box is partitioned by partitioning parts, so that the inside of the housing is divided into a plurality of storage chambers. Here, it has been proposed that a conventional refrigerator has a damper device embedded in a partition part to increase the capacity of the storage chamber (see, for example, Patent Document 1). Specifically, the partition component whose upper surface partially constitutes the lower surface of the storage chamber is formed with a recess for accommodating the lower portion of the damper device behind the portion forming the lower surface of the storage chamber. Further, the partition part in which the recess is formed is provided with a dam projecting upward in front of the recess in order to prevent moisture from entering the recess. The damper device is installed with at least the lower portion embedded in the recess. When the damper device is installed in this way, when the baffle closes the air passage in the damper device, the contact portion between the baffle and the peripheral edge of the air passage in the damper device is arranged below the dam. It will be.

Japanese Unexamined Patent Publication No. 2013-87965

As described above, the contact between the baffle and the peripheral edge of the air passage in the damper device closes the air passage that supplies cold air to the storage chamber. That is, when the air passage is closed, the surface of the baffle on the side in contact with the peripheral edge of the air passage is cooled by the cold air generated by the cooler. At this time, the temperature of the cold air generated by the cooler is as low as about −20 ° C. Therefore, if water adheres to the surface of the baffle on the side that comes into contact with the peripheral edge of the air passage, the water freezes and the peripheral edge of the air passage in the damper device sticks to the baffle, causing the baffle to malfunction. May become. When the baffle malfunctions in this way, it becomes impossible to supply cold air to the storage chamber.

Further, as described above, when the damper device is embedded in the partition component and installed, when the baffle closes the air passage in the damper device, the contact portion between the baffle and the peripheral edge of the air passage in the damper device is formed. It will be placed below the dam. That is, when the damper device is embedded in the partition component and installed, the condition is such that water easily adheres to the surface of the baffle on the side in contact with the peripheral edge of the air passage. Further, when the damper device is embedded in the partition part constituting the lower surface of the storage chamber where the set temperature is in the refrigerating temperature zone, when water spills in the storage chamber, the water does not freeze in the storage chamber, so that the water Is easy to get over the dam. Therefore, when the damper device is embedded in the partition part that constitutes the lower surface of the storage chamber where the set temperature is in the refrigerating temperature zone, even if the water gets over the dam, the side that comes into contact with the peripheral edge of the air passage in the baffle. It is desirable to prevent water from adhering to the surface. The refrigerating temperature zone is a temperature zone higher than 0 ° C. That is, the storage chamber whose set temperature is in the refrigerating temperature zone is a storage chamber whose set temperature is higher than 0 ° C.

Here, as described above, the drive unit of the damper device operates the baffle by the driving force of the motor. Therefore, in order to supply electric power to the motor and transmit a control signal to the motor, it is necessary to connect a lead wire to the drive unit of the damper device. This lead wire is routed while being housed in a groove formed in a heat insulating component around the damper device. At this time, conventionally, the method of routing the lead wire is determined after securing the cross-sectional area of the flow path of the air passage and determining the shape of the recess in which the damper device is embedded. Therefore, there is little degree of freedom in designing the arrangement of the grooves for accommodating the lead wires. Therefore, conventionally, the lead wire portion located in the recess in the plan view may be routed to a position lower than the dam. For this reason, in a conventional refrigerator in which a damper device is embedded in a partition part constituting the lower surface of a storage chamber where the set temperature is in the refrigerating temperature zone, water that has passed over the dam travels through a groove for accommodating lead wires and is baffled. There was a possibility that the baffle would adhere to the surface of the air passage on the side in contact with the peripheral edge of the air passage, and the baffle and the peripheral edge of the air passage in the damper device would stick to each other, resulting in malfunction of the baffle. That is, in the conventional refrigerator in which the damper device is embedded in the partition part constituting the lower surface of the storage chamber where the set temperature is in the refrigerating temperature zone, it is still better to improve the baffle malfunction due to freezing. There was a problem of goodness.

The present invention has been made to solve the above-mentioned problems, and in a refrigerator in which a damper device is embedded in a partition part constituting the lower surface of a storage chamber where a set temperature is a refrigerating temperature zone, a baffle due to freezing is provided. The purpose is to obtain a refrigerator that can suppress malfunctions more than before.

The refrigerator according to the present invention has a storage chamber whose set temperature is in the refrigerating temperature zone, partition parts whose upper surface partially constitutes the lower surface of the storage chamber, and a damper that opens and closes an air passage for supplying air to the storage chamber. The partition component is provided with an apparatus, and the partition component is formed with a recess having an upper portion open behind a portion constituting the lower surface of the storage chamber and accommodating a lower portion of the damper device, and is formed in front of the recess. The damper device includes a baffle that opens and closes a first air passage that is a part of an air passage that supplies air to the storage chamber, and a motor that opens and closes the first air passage. a, a drive unit for operating the baffle by the driving force of the motor, and a lead wire connected to the drive unit, in a state where the front Symbol baffle closes the first air passage, wherein The contact portion between the baffle and the peripheral edge of the first air passage is arranged below the dam, and the portion of the lead wire located in the recess in the plan view is above the dam. Have been placed.

In the refrigerator according to the present invention, among the lead wires connected to the drive unit of the damper device, the portion located in the recess for accommodating the lower portion of the damper device in a plan view is arranged above the dam. .. Therefore, in the refrigerator according to the present invention, the water that has passed over the dam is prevented from adhering to the surface of the baffle on the side that comes into contact with the peripheral edge of the first air passage along the groove for accommodating the lead wire. Can be suppressed. Therefore, the refrigerator according to the present invention can suppress the malfunction of the baffle due to freezing as compared with the conventional case.

It is a front view of the refrigerator which concerns on embodiment of this invention. FIG. 1 is a cross-sectional view taken along the line AA of FIG. It is an exploded perspective view which looked at the damper device of the refrigerator which concerns on embodiment of this invention from the front left side. It is a vertical sectional view of the damper device of the refrigerator which concerns on embodiment of this invention as seen from the right side. It is a perspective view which looked at the damper device of the refrigerator which concerns on embodiment of this invention from the rear right side. It is an exploded perspective view which looked at the damper apparatus part ASSY of the refrigerator which concerns on embodiment of this invention from the rear right side. It is a perspective view which looked at the damper apparatus part ASSY of the refrigerator which concerns on embodiment of this invention from the front left side. It is an exploded perspective view of the partition part of the refrigerator and the damper device part ASSY which concerns on this invention as seen from the front right side. It is an exploded perspective view which looked at a part of the partition part of the refrigerator which concerns on this invention, and the damper apparatus part ASSY from the front left side. It is an exploded perspective view which looked at a part of the partition part of the refrigerator which concerns on this invention, and the damper apparatus part ASSY from the front left side. It is a perspective view which looked at a part of the partition part of the refrigerator which concerns on this invention, and the damper apparatus part ASSY from the front left side. It is a vertical cross-sectional view which looked at a part of the partition part of the refrigerator which concerns on this invention, and the damper apparatus part ASSY from the right side. It is a perspective view which looked at the refrigerator housing and the partition component which concerns on embodiment of this invention from the front right side, and is the figure which shows the state before fixing the partition component to the housing. It is a top view of the part A shown in FIG. It is a perspective view which looked at the vicinity of the storage part of the partition part of the refrigerator which concerns on embodiment of this invention from the front right side, and is the figure which shows the state after fixing the partition part to a housing. It is a vertical cross-sectional view which looked at a part of the partition part of the refrigerator which concerns on this invention, and the damper apparatus part ASSY from the right side. It is a perspective view which looked at the damper apparatus part ASSY of the refrigerator which concerns on embodiment of this invention from the front left side. It is a vertical cross-sectional view of the vicinity of the 2nd groove formed in the heat insulating part of the damper apparatus part ASSY of the refrigerator which concerns on this invention. It is a perspective view which looked at the air passage component which constitutes the back surface of the refrigerating room in the refrigerator which concerns on embodiment of this invention from the front right side. It is a perspective view which looked at the air passage component which constitutes the back surface of the refrigerating room in the refrigerator which concerns on embodiment of this invention from the rear right side. It is an exploded perspective view which looked at the air passage component which constitutes the back surface of the refrigerating room in the refrigerator which concerns on embodiment of this invention from the front right side.

Embodiment.
Hereinafter, an example of the refrigerator according to the present invention will be described with reference to the drawings.

FIG. 1 is a front view of a refrigerator according to an embodiment of the present invention. FIG. 2 is a cross-sectional view taken along the line AA of FIG.
The refrigerator 100 includes a box-shaped housing 90 having an open front surface. The housing 90 includes an outer box 53 that constitutes an outer peripheral surface portion of the housing 90, and an inner box 52 that constitutes an inner peripheral surface portion of the housing 90. Further, a heat insulating material 34 such as urethane foam is provided between the outer box 53 and the inner box 52. A vacuum heat insulating material may be provided as the heat insulating material 34 between the outer box 53 and the inner box 52.

The inside of the housing 90 is partitioned by partitioning parts. As a result, the housing 90 is formed with a plurality of storage chambers having an opening on the front surface. In the case of the present embodiment, the inside of the housing 90 is vertically partitioned by the partition component 35, the partition component 36, and the partition component 37. Further, the partition part 35 and the partition part 36 are also partitioned in the lateral direction by a partition part (not shown). As a result, the refrigerator 100 includes a refrigerating room 1, an ice making room 2, a small freezing room 3, a freezing room 4, and a vegetable room 5 as storage rooms.

Specifically, the refrigerating room 1 is arranged at the top of the storage room. That is, the refrigerator 100 according to the present embodiment is a worktop type refrigerator. The ice making chamber 2 and the small freezing chamber 3 are arranged below the refrigerating chamber 1. That is, a part of the upper surface of the partition component 35 constitutes the lower surface of the refrigerating chamber 1. Here, the refrigerating room 1 is a storage room in which the set temperature is in the refrigerating temperature zone. The refrigerating temperature zone is a temperature zone higher than 0 ° C. That is, the storage chamber whose set temperature is in the refrigerating temperature zone is a storage chamber whose set temperature is higher than 0 ° C. Therefore, the partition component 35 constitutes the lower surface of the storage chamber whose set temperature is in the refrigerating temperature zone by a part of the upper surface. A part of the lower surface of the partition component 35 constitutes the upper surface of the ice making chamber 2 and the small freezing chamber 3. A part of the upper surface of the partition component 36 constitutes the lower surface of the ice making chamber 2 and the small freezing chamber 3. The freezing chamber 4 is arranged below the ice making chamber 2 and the small freezing chamber 3. That is, a part of the lower surface of the partition component 36 constitutes the upper surface of the freezing chamber 4. Further, a part of the upper surface of the partition component 37 constitutes the lower surface of the freezing chamber 4. The vegetable compartment 5 is arranged below the freezing chamber 4. That is, a part of the lower surface of the partition part 37 constitutes the upper surface of the vegetable compartment 5. The refrigerating room 1, the ice making room 2, the small freezing room 3, the freezing room 4, and the vegetable room 5 are examples of storage rooms of the refrigerator 100. The type and arrangement of the storage chamber provided in the refrigerator 100 is not limited to the above configuration.

Each opening formed on the front surface of these storage chambers is covered with a door so as to be openable and closable. Specifically, a left door 6 and a right door 7 are provided in the opening on the front surface of the refrigerator compartment 1. The left end of the left door 6 is rotatably connected to the housing 90. The right end of the right door 7 is rotatably connected to the housing 90. That is, the opening on the front surface of the refrigerator compartment 1 is covered with a double door that can be opened and closed. The opening on the front surface of the ice making chamber 2 is covered with a pull-out door 33 so as to be openable and closable. The opening on the front surface of the small freezer 3 is covered with a pull-out door 30 so as to be openable and closable. The opening on the front surface of the freezing chamber 4 is covered with a drawer-type door 31 so as to be openable and closable. The opening on the front surface of the vegetable compartment 5 is covered with a pull-out door 32 so as to be openable and closable.

In the refrigerator compartment 1, a plurality of pockets 20 for storing stored items are provided at different positions in the height direction. In this embodiment, the three pockets 20 are attached to at least one of the left door 6 and the right door 7. Further, the inside of the refrigerating room 1 is divided by three shelves 19. Below the shelf 19, which is the lowermost stage, is a chilled chamber 17. The chilled chamber 17 is set to a temperature lower than the temperature of the refrigerating chamber 1. For example, when the temperature of the refrigerating chamber 1 is about 3 ° C., the chilled chamber 17 is set to, for example, about 0 ° C. The chilled chamber 17 is provided with a case 18 for storing stored items. Further, the small freezing room 3 is provided with a case 25 for storing stored items. Further, the freezing chamber 4 is provided with an upper case 26 and a lower case 27 for storing stored items. Further, the vegetable compartment 5 is provided with an upper case 28 and a lower case 29 for storing stored items.

Refrigerator 100 includes a refrigeration cycle to cool each storage chamber. This refrigeration cycle is a general one, and is configured by sequentially connecting a compressor 14, a condenser (not shown), a drawing mechanism such as a capillary tube (not shown), and a cooler 11. That is, the refrigerant compressed to high temperature and high pressure by the compressor 14 is sent to the condenser, and heat is mainly dissipated to the outside of the refrigerator 100 to condense. The condensed refrigerant is depressurized by the drawing mechanism and then sent to the cooler 11. Then, the refrigerant sent to the cooler 11 cools the air around the cooler 11.

The cooler 11 is provided in the cooler chamber 91 formed behind the freezing chamber 4. The cooler chamber 91 is partitioned from the freezing chamber 4 by a fan grill 15. That is, the cooler 11 cools the air in the cooler chamber 91. Further, the cooler chamber 91 and each storage chamber communicate with each other by an air passage. The cooler chamber 91 is provided with an internal fan 10 on the downstream side of the cooler 11. That is, by driving the internal fan 10, the air cooled by the cooler 11 circulates and cools each storage chamber.

For example, an air passage component 21 is provided at the rear of the housing 90. The air passage component 21 constitutes the back surface of the refrigerating chamber 1. As described above, the chilled chamber 17 is also formed in the refrigerating chamber 1. The air passage component 21 also constitutes the back surface of the chilled chamber 17. An air passage 24 is formed in the air passage component 21. Further, the air passage component 21 is formed with, for example, a plurality of air outlets 22 that communicate the air passage 24 and the refrigerating chamber 1. That is, the cold air supplied from the cooler chamber 91 to the air passage 24 is blown out from the air outlet 22 into the refrigerator chamber 1. Further, the air passage 24 communicates with the cooler chamber 91 via an air passage or the like formed in the damper device 9 described later. That is, the air passage 24 and the air outlet 22 form an air passage for supplying air from the cooler chamber 91 to the refrigerating chamber 1 together with the air passage and the like formed in the damper device 9 described later. The air passage component 21 is also formed with an air passage for supplying air from the cooler chamber 91 to the chilled chamber 17. In the present embodiment, the air passage component 21 includes an air passage 80, which will be described later, communicating with the cooler chamber 91 as an air passage for supplying air from the cooler chamber 91 to the chilled chamber 17, and the air passage 80 and the chilled. An air outlet 23 that communicates with the chamber 17 is formed. That is, the cold air supplied from the cooler chamber 91 to the air passage 80 is blown out from the outlet 23 into the chilled chamber 17.

Here, the cold air generated by the cooler 11 is about −20 ° C., which is lower than the set temperature of the refrigerating chamber 1. Therefore, a damper device 9 is provided between the air passage 24 of the air passage component 21 and the cooler chamber 91. Then, by opening and closing the air passage for supplying air from the cooler room 91 to the refrigerating room 1 by the damper device 9, the amount of cold air supplied from the cooler room 91 to the refrigerating room 1 is adjusted, and the inside of the refrigerating room 1 is adjusted. The temperature of is kept near the set temperature.

Specifically, the refrigerator 100 includes a temperature sensor 38 that detects the temperature inside the refrigerator compartment 1. The temperature sensor 38 is attached to the surface of the air passage component 21, for example. If the temperature inside the refrigerating chamber 1 can be detected, the installation position of the temperature sensor 38 is arbitrary. Further, the damper device 9 includes a baffle 45 that opens and closes an air passage formed in the damper device 9. Further, the refrigerator 100 includes a control board 16 for operating the baffle 45 based on the temperature detected by the temperature sensor 38. The control board 16 operates the baffle 45 so that the temperature detected by the temperature sensor 38 becomes the set temperature of the refrigerating chamber 1, and adjusts the amount of cold air supplied from the cooler chamber 91 to the refrigerating chamber 1. The cold air supplied to the refrigerating chamber 1 returns to the cooler chamber 91 through a return air passage (not shown), and is cooled again by the cooler 11.

In the present embodiment, the control board 16 controls other than the operation of the baffle 45. For example, in the refrigerator 100 according to the present embodiment, a heater for temperature compensation is provided in at least a part of the storage chambers. Further, in the refrigerator 100 according to the present embodiment, a heater for preventing dew is installed on a partition plate 8 or the like arranged between the left door 6 and the right door 7. The control board 16 also controls energization of these heaters.

By the way, in the conventional refrigerator, there is a refrigerator separately provided with a cooler for cooling the air supplied to the freezing chamber and a cooler for cooling the air supplied to the refrigerating chamber. In this type of refrigerator, air can be cooled to a temperature close to the set temperature of the refrigerating chamber by a cooler, and the air can be supplied to the refrigerating chamber. For this reason, this type of refrigerator often does not require a damper device for adjusting the amount of cold air supplied to the refrigerator. However, this type of refrigerator needs to be equipped with an internal fan corresponding to each cooler. Further, in this type of refrigerator, the temperature of the air supplied to the storage chamber is determined by the flow rate of the refrigerant flowing through each cooler, so that the control of the flow rate of the refrigerant flowing through each cooler becomes very complicated.

On the other hand, the refrigerator 100 according to the present embodiment supplies the air cooled by the same cooler 11 to both the refrigerating chamber 1 and the freezing chamber 4. Therefore, as described above, in the refrigerator 100 according to the present embodiment, it is necessary to adjust the amount of cold air supplied to the refrigerating chamber 1 by the damper device 9. However, the refrigerator 100 according to the present embodiment can easily control the flow rate of the refrigerant flowing to the cooler 11, and can easily control the temperature in the refrigerating chamber 1.

As the refrigerator 100 continues to operate, frost adheres to the cooler 11. Therefore, the refrigerator 100 includes a defrost heater 12 that melts the frost adhering to the cooler 11. The energization of the defrost heater 12 is controlled by the control board 16. Further, the refrigerator 100 includes a drain pan 13 that receives water generated by defrosting the cooler 11. The drain pan 13 is installed in a machine room 92 formed in the lower part of the housing 90. A compressor 14 is also installed in the machine room 92. Therefore, the temperature inside the machine room 92 is relatively high. Therefore, the water discharged to the drain pan 13 evaporates.

Next, the details of the damper device 9 will be described.

FIG. 3 is an exploded perspective view of the damper device of the refrigerator according to the embodiment of the present invention as viewed from the front left side. That is, FIG. 3 is an exploded perspective view of the damper device 9 as viewed from the front left side of the refrigerator 100. FIG. 4 is a vertical cross-sectional view of the damper device of the refrigerator according to the embodiment of the present invention as viewed from the right side. That is, in FIG. 4, the left side of the paper surface is the front side of the refrigerator 100 and is the front side of the damper device 9, and the right side of the paper surface is the rear side of the refrigerator 100 and is the rear side of the damper device 9. Note that FIG. 4A shows the state of the damper device 9 in which the first air passage 47 is open. FIG. 4B shows the state of the damper device 9 in which the first air passage 47 is closed. Further, FIG. 5 is a perspective view of the damper device of the refrigerator according to the embodiment of the present invention as viewed from the rear right side. That is, FIG. 5 is a perspective view of the damper device 9 as viewed from the rear right side of the refrigerator 100. In the following, when the front-back direction and the left-right direction of the configuration of the refrigerator 100 are described, it is assumed that the configuration indicates the direction in which the refrigerator 100 is installed.

The damper device 9 includes a drive unit 39, a frame unit 40, and a baffle 45. The housing of the drive unit 39 and the frame unit 40 are fastened with screws 41. The drive unit 39 includes, for example, a motor 42, which is a stepping motor, and a plurality of gears 43 that reduce the rotation of the motor 42. Further, the drive unit 39 is connected to one of the plurality of gears 43, and includes a driving pin 44 that outputs the rotation of the motor 42 after deceleration by the plurality of gears 43. The driving pin 44 is connected to one of the lateral ends of the baffle 45. That is, the drive unit 39 operates the baffle 45 by the drive force of the motor 42.

A first air passage 47, which is a through hole, is formed in the frame portion 40. The first air passage 47 is an air passage that connects the cooler chamber 91 and the air passage 24 of the air passage component 21. That is, the first air passage 47 constitutes a part of the air passage that supplies air from the cooler chamber 91 to the refrigerating chamber 1. Further, the frame portion 40 is provided with a rib 48 projecting upward on the peripheral edge portion of the first air passage 47.

The baffle 45 opens and closes the first air passage 47, and is arranged above the first air passage 47 of the frame portion 40. One of the lateral ends of the baffle 45 is connected to the driving pin 44 of the drive unit 39 as described above. Further, the other of the lateral ends of the baffle 45 is rotatably connected to the frame portion 40. The other center of rotation of the lateral end of the baffle 45 is located coaxially with the central axis of the driving pin 44. Therefore, the baffle 45 can swing around the central axis of the driving pin 44 by the driving force of the motor 42 of the driving unit 39.

The baffle 45 is provided with a sealing material 46 on one side. The sealing material 46 is, for example, a polyethylene sealing material that contains almost no water. As shown in FIG. 4B, when the baffle 45 rotates so as to approach the first air passage 47, the sealing material 46 comes into contact with the rib 48 on the periphery of the first air passage 47 from above. As a result, the first air passage 47 is closed, and the air passage that supplies air from the cooler chamber 91 to the refrigerating chamber 1 is also closed. Further, as shown in FIG. 4A, when the baffle 45 rotates so as to be separated from the first air passage 47, the sealing material 46 is separated from the rib 48 on the periphery of the first air passage 47. As a result, the first air passage 47 is opened, and the air passage for supplying air from the cooler chamber 91 to the refrigerating chamber 1 is also opened.

Here, as described above, the drive unit 39 of the damper device 9 operates the baffle 45 by the drive force of the motor 42. Therefore, in order to supply electric power to the motor 42 and transmit a control signal to the motor 42, it is necessary to connect a lead wire to the drive unit 39 of the damper device 9. Therefore, the damper device 9 includes a lead wire 68 described later. As shown in FIG. 5, the drive unit 39 includes a connection unit 49 at the upper part of the right rear portion. The lead wire 68, which will be described later, is connected to the connection portion 49 by using, for example, a connector.

The damper device 9 according to the present embodiment is a damper device in which only the first air passage 47 communicating with the refrigerating chamber 1 is formed as an air passage communicating with the storage chamber. That is, the damper device 9 according to the present embodiment is a so-called single type damper device. However, in the conventional damper device, there is also a damper device in which two air passages communicating with different storage chambers are formed, and each air passage is opened and closed by two independently operating baffles. That is, there is also a so-called twin type damper device in the conventional damper device. The damper device 9 according to the present embodiment may be such a twin type damper device. When the damper device 9 is a twin type, it is possible to adjust the amount of cold air supplied to the refrigerating room 1 in addition to the amount of cold air supplied to the refrigerating room 1 by the damper device 9. Become.

Subsequently, the installation configuration of the damper device 9 will be described.
The front portion of the upper surface of the partition component 35 constitutes the lower surface of the refrigerating chamber 1. The damper device 9 is installed so that the lower portion of the damper device 9 is embedded behind a portion of the partition component 35 that constitutes the lower surface of the refrigerating chamber 1. In the present embodiment, the damper device 9 and the heat insulating component 59 installed on the upper part of the damper device 9 are assembled in advance as the damper device unit ASSY64. Then, the damper device unit ASSY64 is attached to the partition part 35. Therefore, in the following, the damper device unit ASSY64 will be described first. After that, how to attach the damper device unit ASSY64 to the partition component 35 will be described.

FIG. 6 is an exploded perspective view of the damper device assembly ASSY of the refrigerator according to the embodiment of the present invention as viewed from the rear right side. Further, FIG. 7 is a perspective view of the damper device assembly ASSY of the refrigerator according to the embodiment of the present invention as viewed from the front left side.
The heat insulating component 59 is a component made of a heat insulating material such as expanded styrene. The heat insulating component 59 is combined with the damper device 9 so as to cover the damper device 9 from above. A second air passage 55a is formed in the heat insulating component 59. The second air passage 55a is arranged at a position above the first air passage 47 of the damper device 9 and below the air passage 24 of the air passage component 21. Then, the second air passage 55a communicates with the first air passage 47 of the damper device 9 and the air passage 24 of the air passage component 21, and a part of the air passage that supplies air from the cooler chamber 91 to the refrigerating chamber 1 is provided. It will be configured. The heat insulating component 59 is also formed with an air passage 56a that communicates with the air passage 80 described later of the air passage component 21. That is, the air passage 56a constitutes a part of the air passage that supplies air from the cooler chamber 91 to the chilled chamber 17.

FIG. 8 is an exploded perspective view of the refrigerator partition parts and the damper device assembly ASSY according to the present invention as viewed from the front right side. 9 and 10 are exploded perspective views of a part of the partition parts of the refrigerator and the damper device assembly ASSY according to the present invention as viewed from the front left side. FIG. 11 is a perspective view of a part of the partition parts of the refrigerator and the damper device assembly ASSY according to the present invention as viewed from the front left side. Further, FIG. 12 is a vertical cross-sectional view of a part of the partition parts of the refrigerator and the damper device assembly ASSY according to the present invention as viewed from the right side.

The partition component 35 includes an upper member 50, a lower member 51, and a heat insulating component 54. The upper member 50 is made of, for example, resin, and is a member that constitutes the upper surface portion of the partition component 35. In other words, the front portion of the upper surface of the upper member 50 constitutes the lower surface of the refrigerating chamber 1. The lower member 51 is made of, for example, resin, and is a member that constitutes the lower surface portion of the partition component 35. The heat insulating component 54 is made of a heat insulating material such as expanded styrene. In a plan view, the heat insulating component 54 is arranged between the upper member 50 and the lower member 51 behind the portion forming the lower surface of the refrigerating chamber 1 in the partition component 35. The upper member 50 and the lower member 51 are fixed with screws 41 with the heat insulating component 54 sandwiched between them. The partition component 35 has a hollow inside in a state before being attached to the housing 90. Then, when the partition component 35 is attached to the inner box 52 of the housing 90 and the heat insulating material 34 is foam-filled between the inner box 52 and the outer box 53, the partition component 35 is formed through a through hole formed on the side surface of the partition component 35. The heat insulating material 34 is filled and foamed inside.

The heat insulating component 54 is formed with a recess 81 having an open top. Further, an opening is formed in the range of the upper member 50 facing the recess 81. The recess 81 is formed, for example, in a substantially central portion in the left-right direction. The lower portion of the damper device 9 is housed in the recess 81. Further, in the present embodiment, the lower portion of the heat insulating component 59 is also housed in the recess 81. Specifically, the sealing material 58 is attached to the bottom of the recess 81 in a range facing the lower portion of the heat insulating component 59. In this state, the lower portion of the damper device portion ASSY64, that is, the lower portion of the damper device 9 and the lower portion of the heat insulating component 59 are housed in the recess 81. The upper member 50 of the partition component 35 is provided with a dam 69 projecting upward in front of the recess 81 in order to prevent water spilled in the refrigerator chamber 1 from entering the recess 81.

Further, an air passage 55b and an air passage 56b are formed in the recess 81. An opening is formed in the range of the lower member 51 facing the air passage 55b and the air passage 56b. The air passage 55b is arranged at a position below the first air passage 47 of the damper device 9 and above the cooler chamber 91. The air passage 55b communicates with the first air passage 47 of the damper device 9 and the cooler chamber 91, and forms a part of the air passage that supplies air from the cooler chamber 91 to the refrigerator chamber 1. Further, the air passage 56b is arranged at a position below the air passage 56a of the heat insulating component 59 and above the cooler chamber 91. The air passage 56b communicates with the air passage 56a of the heat insulating component 59 and the cooler chamber 91, and forms a part of the air passage that supplies air from the cooler chamber 91 to the chilled chamber 17.

Further, the heat insulating component 54 is also formed with an air passage 57 which is a part of a return air passage for returning cold air from the refrigerating chamber 1 to the cooler chamber 91. The air passage 57 is formed on the right side of the recess 81, for example. A slit-shaped opening 65 is formed at a portion of the upper member 50 facing the air passage 57 so that the air passage 57 is not blocked by the upper member 50. Further, an opening is also formed in a portion of the lower member 51 facing the air passage 57 so that the air passage 57 is not blocked by the lower member 51.

The damper device unit ASSY 64, whose lower portion is housed in the recess 81 of the partition component 35, is covered with, for example, a resin cover 60 from above. The cover 60 has an opening formed at the upper portion, and covers the outer peripheral edge of the upper surface portion of the heat insulating component 59 so as not to block the second air passage 55a and the air passage 56a of the heat insulating component 59 of the damper device portion ASSY64. ing. Further, a second sealing material 63 is attached to the upper surface of the heat insulating component 59 in a range not covered by the cover 60. The second sealing material 63 is formed with an opening at a position facing the second air passage 55a and the air passage 56a so as not to block the second air passage 55a and the air passage 56a of the heat insulating component 59. The damper device portion ASSY 64 is fixed by fixing the cover 60 to the upper member 50 of the partition component 35 with screws 41.

By embedding the damper device 9 in the partition component 35 in this way and installing it, the volume of the refrigerating chamber 1 can be expanded. On the other hand, as shown in FIG. 12, by embedding the damper device 9 in the partition component 35 in this way and installing the damper device 9, in a state where the baffle 45 closes the first air passage 47, the sealing material 46 of the baffle 45 and the baffle 45 The contact portion with the rib 48 on the periphery of the first air passage 47 is arranged below the dam 69.

Electrical components such as a drive unit 39 of the damper device 9 and a heater (not shown) are attached to the partition component 35. Therefore, on the rear left side of the partition component 35, a storage portion 62 for accommodating the end portions of the lead wires of these electrical components is provided. For example, among the lead wires 68 to be described later connected to the drive unit 39 of the damper device 9, the end portion on the side connected to the connection portion 49 of the drive unit 39 is set as the first end portion 68a, and the first end portion 68a and the lead wire 68. The opposite end is the second end 68b. In this case, the second end portion 68b of the lead wire 68 is housed in the storage portion 62. See also FIG. 6 for the first end 68a of the lead wire 68. See also FIG. 15 below for the second end 68b of the lead wire 68.

Subsequently, a method of attaching the partition component 35 to which the damper device unit ASSY 64 is attached to the housing 90 will be described.

FIG. 13 is a perspective view of the refrigerator housing and partition parts according to the embodiment of the present invention as viewed from the front right side, and is a view showing a state before fixing the partition parts to the housing. FIG. 14 is a plan view of part A shown in FIG. Further, FIG. 15 is a perspective view of the vicinity of the storage portion of the partition component of the refrigerator according to the embodiment of the present invention as viewed from the front right side, and is a view showing a state after the partition component is fixed to the housing. As described above, the storage portion 62 of the partition component 35 houses the end of the lead wire connected to the electrical component attached to the partition component 35. In FIGS. 14 and 15, these lead wires stored in the storage unit 62 are shown as lead wires 66. That is, a part of the lead wire 66 is the lead wire 68 connected to the drive unit 39 of the damper device 9. Further, the end on the side of the lead wire 68 stored in the storage portion 62 is the second end portion 68b.

When attaching the partition component 35 to the housing 90, first, the partition component 35 is fixed at a predetermined position of the housing 90. In the inner box 52 of the housing 90, the other end of the main body lead wire 61 whose one end is connected to the control board 16 or the like is exposed from a position near the storage portion 62 of the partition component 35. After fixing the partition component 35 at a predetermined position of the housing 90, the lead wire 66 stored in the storage portion 62 of the partition component 35 and the main body lead wire 61 are connected by using, for example, a connector.

Specifically, the upper surface of the storage portion 62 is closed with a lid 67 so as to be openable and closable. Therefore, when connecting the lead wire 66 and the main body lead wire 61, first, the lid 67 is opened and the lead wire 66 is taken out from the storage portion 62. Then, the lead wire 66 and the main body lead wire 61 are connected by using, for example, a connector. After that, the lead wire 66 is stored in the storage unit 62 again, and the lid 67 is closed. In the present embodiment, the lid 67 is swingable with the front end as a fulcrum.

Subsequently, how to route the lead wire 68 connected to the drive unit 39 of the damper device 9 will be described.

FIG. 16 is a vertical cross-sectional view of a part of the partition parts of the refrigerator and the damper device assembly ASSY according to the present invention as viewed from the right side. Further, FIG. 17 is a perspective view of the damper device assembly ASSY of the refrigerator according to the embodiment of the present invention as viewed from the front left side. FIG. 18 is a vertical cross-sectional view of the vicinity of the second groove formed in the heat insulating component of the damper device unit ASSY of the refrigerator according to the present invention. The alternate long and short dash line shown in FIG. 16 indicates the height of the dam 69.

In a conventional refrigerator in which a damper device is embedded in a partition part, a lead wire portion located in a recess in which the damper device is embedded in a plan view may be routed to a place lower than a dam. Here, when the damper device is embedded in the partition part constituting the lower surface of the storage chamber whose set temperature is in the refrigerating temperature zone, when water spills in the storage chamber, the water does not freeze in the storage chamber. Water easily gets over the dam. For this reason, in a conventional refrigerator in which a damper device is embedded in a partition part constituting the lower surface of a storage chamber where the set temperature is in the refrigerating temperature zone, water that has passed over the dam is transmitted through a groove or the like for accommodating the lead wire. There was a possibility that the baffle would adhere to the surface of the baffle on the side in contact with the peripheral edge of the air passage, and the baffle and the peripheral edge of the air passage in the damper device would stick to each other, resulting in malfunction of the baffle.

On the other hand, in the refrigerator 100 according to the present embodiment, since the damper device 9 is embedded in the partition component 35 constituting the lower surface of the refrigerating chamber 1 whose set temperature is in the refrigerating temperature zone, water spilled in the refrigerating chamber 1 Is easy to get over the dam 69. However, in the refrigerator 100 according to the present embodiment, of the lead wires 68 connected to the drive unit 39 of the damper device 9, the portion of the lead wire 68 located in the recess 81 of the partition component 35 in a plan view is the partition component 35. It is arranged above the dam 69 provided on the upper surface. Therefore, in the refrigerator 100 according to the present embodiment, the water that has passed over the dam 69 travels through the groove for accommodating the lead wire 68 to the surface of the baffle 45 on the side of the baffle 45 that comes into contact with the rib 48 on the periphery of the first air passage 47. Adhesion can be suppressed more than before. Therefore, the refrigerator 100 according to the present embodiment can suppress the malfunction of the baffle 45 due to freezing as compared with the conventional case.

Specifically, as shown in FIG. 16, in a state where the damper device 9 is fixed to the partition component 35, the connecting portion 49 of the driving unit 39 to which the first end portion 68a of the lead wire 68 is connected is the dam 69. It is located higher than. Then, as shown in FIGS. 6, 7 and 17, the portion of the lead wire 68 arranged in the heat insulating component 59 located in the recess 81 of the partition component 35 in the plan view is the dam 69. It is located higher than.

Specifically, when looking at the lead wire 68 from the first end portion 68a connected to the connection portion 49 of the drive unit 39 toward the second end portion 68b, the lead wire 68 is routed as follows. Has been done. First, the lead wire 68 extends from the connecting portion 49 to the upper surface of the driving portion 39 along the side surface of the driving unit 39. Then, on the upper surface of the drive unit 39, the lead wire 68 extends toward the first air passage 47. In the present embodiment, the lead wires 68 arranged on the side surfaces and the upper surface of the drive unit 39 are fixed with tape 70 so as not to come apart.

The lead wire 68 routed to the end on the first air passage 47 side on the upper surface of the drive unit 39 of the damper device 9 is routed on the surface of the heat insulating component 59 combined with the upper part of the damper device 9 as follows. NS. First, the lead wire extends through the second air passage 55a of the heat insulating component 59 to the upper surface of the heat insulating component 59. The lead wire 68 arranged on the upper surface portion of the heat insulating component 59 extends from the second air passage 55a to the front end portion of the upper surface portion and is arranged along the front end portion. Specifically, when looking at the lead wire 68 from the first end portion 68a to the second end portion 68b, the lead wire 68 arranged along the front end portion of the upper surface portion of the heat insulating component 59 is It extends toward the left edge. The left end portion of the heat insulating component 59 is an end portion that becomes the storage portion 62 side when the heat insulating component 59 is fixed to the partition component 35 as the damper device portion ASSY64. In the present embodiment, the lead wires 68 arranged on the upper surface of the heat insulating component 59 are fixed with tape 70 so as not to come apart.

More specifically, the heat insulating component 59 is provided with a groove in which the lead wire 68 is arranged so that the lead wire 68 can be easily routed on the surface of the heat insulating component 59. Specifically, the heat insulating component 59 includes a first groove 71, a second groove 72, and a third groove 73 as the groove. The first groove 71 is formed on the inner wall portion of the second air passage 55a in the vertical direction at a position or the like at a corner portion of the second air passage 55a in a plan view. The second groove 72 is formed on the upper surface of the heat insulating component 59. The second groove 72 communicates with the first groove 71 and the front end portion of the upper surface portion of the heat insulating component 59. The third groove 73 is formed at the front end portion of the upper surface portion of the heat insulating component 59 along the front end portion. The third groove 73 communicates with the second groove 72. Further, the third groove 73 is open upward and forward. The lead wires 68 are arranged in the first groove 71, the second groove 72, and the third groove 73.

Further, in at least a part of the first groove 71 and the second groove 72, the lead wire 68 and the inner wall surface of the groove are closed by the first sealing material 74. As shown in FIG. 18, in the present embodiment, in at least a part of the second groove 72, the lead wire 68 and the inner wall surface of the groove are closed by the first sealing material 74. Further, in the present embodiment, the tape-shaped first sealing material 74 is wound around the lead wire 68, and the lead wire 68 portion around which the first sealing material 74 is wound is inserted into the second groove 72. As a result, in at least a part of the second groove 72, the lead wire 68 and the inner wall surface of the groove are closed by the first sealing material 74. As described above, the second sealing material 63 is attached to the upper surface of the heat insulating component 59. The second sealing material 63 is provided so as to cover the first groove 71 and the second groove 72 from above. By providing the first sealing material 74 and the second sealing material 63, it is possible to prevent cold air from leaking from the first groove 71 and the second groove 72.

The above-mentioned lead wire 68 is routed to the drive unit 39 and the heat insulating component 59 when the damper device unit ASSY 64 is assembled. Therefore, the damper device unit ASSY 64, in which the lead wire 68 is routed around the drive unit 39 and the heat insulating component 59, is attached to the partition component 35. That is, as shown in FIG. 9 and the like, the sealing material 58 is attached to the bottom of the recess 81 of the partition component 35. After that, the lower part of the damper device portion ASSY64 around which the lead wire 68 is routed is inserted into the recess 81 of the partition component 35. Then, as shown in FIGS. 10 and 11, for example, a resin cover 60 is covered from above the damper device portion ASSY 64, and the cover 60 is fixed to the upper member 50 of the partition component 35 with screws 41, and the damper device section is formed. Fix ASSY64. After that, the second sealing material 63 is attached to the upper surface of the heat insulating component 59, and the lead wire 68 is securely fixed. Then, after fixing the damper device unit ASSY64 to the partition part 35, the lead wire 68 is routed in the partition part 35, and the second end portion 68b is stored in the storage portion 62.

Here, in the refrigerator described in Patent Document 1, the lead wire connected to the drive unit is exposed from the bottom of the recess of the partition component that houses the lower portion of the damper device. Further, the length of the exposed portion of the lead wire is such that the lead wire can be connected to the drive unit before the damper device is housed in the recess. Therefore, in the refrigerator described in Patent Document 1, when the lower portion of the damper device is stored in the bottom of the recess of the partition part, the lead wire is folded and stored between the lower portion of the damper device and the bottom of the recess. Will be done. At this time, in the refrigerator described in Patent Document 1, since the lead wire cannot be seen, it cannot be confirmed whether the lead wire is properly folded and stored.

Therefore, in the refrigerator described in Patent Document 1, a lead wire may be caught between the damper device and the recess, and the damper device may not be installed at a proper position. Further, in the refrigerator described in Patent Document 1, the damper device cannot be installed in a regular position, and the parts to be attached to the upper part of the damper device may not be installed in the regular position. As a result, cold air may leak from the periphery of the damper device. In addition, water may enter the damper device through a gap around the damper device and freeze, resulting in malfunction of the baffle. In addition, there is a possibility that the lead wire may be broken due to the lead wire being sandwiched between the damper device and the recess.

On the other hand, in the refrigerator 100 according to the present embodiment, since the lead wire 68 is routed as described above, the lead wire 68 is arranged in the recess 81 of the partition component 35 in the damper device unit ASSY 64. Not done. Therefore, when the lower portion of the damper device portion ASSY 64 is housed in the recess 81 of the partition component 35, the lead wire 68 is not sandwiched between the damper device portion ASSY 64 and the recess 81.

Further, in the refrigerator 100 according to the present embodiment, since the lead wire 68 is routed as described above, when the parts such as the cover 60 and the second sealing material 63 are attached to the upper part of the damper device unit ASSY 64, the lead wire It can be confirmed whether or not 68 is arranged in the regular position. Therefore, when the lead wire 68 is not arranged at a proper position, the arrangement of the lead wire 68 can be corrected in advance before mounting the component on the upper portion of the damper device portion ASSY64. Therefore, in the refrigerator 100 according to the present embodiment, the parts attached to the upper part of the damper device unit ASSY64 can be attached to the regular positions.

Therefore, in the refrigerator 100 according to the present embodiment, it is possible to suppress cold air leakage from the periphery of the damper device unit ASSY 64, malfunction of the baffle 45 due to freezing, and disconnection of the lead wire 68 as compared with the conventional case.

An air passage component 21 constituting the back surface of the refrigerating chamber 1 is provided above the second sealing material 63 provided on the upper surface of the heat insulating component 59 of the damper device unit ASSY 64. Finally, the configuration of the air passage component 21 will be described.

FIG. 19 is a perspective view of the air passage components constituting the back surface of the refrigerator compartment in the refrigerator according to the embodiment of the present invention as viewed from the front right side. FIG. 20 is a perspective view of the air passage components constituting the back surface of the refrigerator compartment in the refrigerator according to the embodiment of the present invention as viewed from the rear right side. Further, FIG. 21 is an exploded perspective view of the air passage components constituting the back surface of the refrigerator compartment in the refrigerator according to the embodiment of the present invention as viewed from the front right side.

The air passage component 21 is fixed to the housing 90 by screws, claws, and the like. The air passage component 21 includes a front side component 75, a first heat insulating component 76, and a second heat insulating component 77. The front side component 75 is a component that constitutes the front surface portion of the air passage component 21. That is, the front side component 75 is a component that constitutes the back surface of the refrigerating chamber 1 and the back surface of the chilled chamber 17. A temperature sensor 38 for detecting the temperature inside the refrigerating chamber 1 is provided at a position forming the back surface of the refrigerating chamber 1 in the front side component 75. A temperature sensor 78 for detecting the temperature inside the chilled chamber 17 is provided at a position forming the back surface of the chilled chamber 17 in the front side component 75.

The first heat insulating component 76 is formed of a heat insulating material such as expanded styrene, and is provided on the back surface of the front side component 75. The first heat insulating component 76 is formed with two grooves extending in the vertical direction. These grooves are open on the lower surface and the back surface. The second heat insulating component 77 is formed of a heat insulating material such as expanded styrene, and is provided on the back surface of the first heat insulating component 76. The openings on the back surface side of the two grooves formed in the first heat insulating component 76 are closed by the second heat insulating component 77.

As a result, two air passages with an open lower portion are formed between the first heat insulating component 76 and the second heat insulating component 77. One of these two air passages is an air passage 24 that forms a part of the air passage that supplies air from the cooler chamber 91 to the refrigerating chamber 1. Further, one of these two air passages is an air passage 80 that forms a part of the air passage that supplies air from the cooler chamber 91 to the chilled chamber 17. Further, the front side component 75 and the first heat insulating component 76 are formed with through holes communicating the front of the front side component 75 and the air passage 24 at positions on the back side of the refrigerating chamber 1. The through hole serves as an outlet 22 for blowing cold air into the refrigerating chamber 1. Further, the front side component 75 and the first heat insulating component 76 are formed with through holes communicating the front of the front side component 75 and the air passage 80 at positions on the back side of the chilled chamber 17. The through hole serves as an outlet 23 for blowing cold air into the chilled chamber 17.

A covering portion 79 extending in the left-right direction and projecting forward is provided at the lower end portion of the front side component 75. The lower surface of the covering portion 79 has a shape that descends toward the front. Then, as shown in FIG. 12, the covering portion 79 is configured to cover the dam 69 of the partition component 35 from above when the air passage component 21 is attached to the upper part of the damper device portion ASSY64. If high humidity air flows into the refrigerating chamber 1 when the left door 6 and the right door 7 of the refrigerating chamber 1 are opened, dew may occur on the front surface of the front side component 75. By providing the covering portion 79, even if the dew adhering to the front surface of the front surface side component 75 drips downward, it is possible to prevent the dew from entering the damper device 9 side, and the baffle 45 malfunctions due to freezing. Can be suppressed.

As described above, the refrigerator 100 according to the present embodiment includes the refrigerating chamber 1, the partition parts 35 whose upper surface partially constitutes the lower surface of the refrigerating chamber 1, and the damper device that opens and closes the air passage for supplying air to the refrigerating chamber 1. 9 and. The partition component 35 has an open upper portion and a recess 81 for accommodating the lower portion of the damper device 9 is formed behind a portion forming the lower surface of the refrigerating chamber 1. Further, the partition component 35 is provided with a dam 69 projecting upward in front of the recess 81. The damper device 9 is formed with a first air passage 47 which is a part of an air passage for supplying air to the refrigerator 100. Further, the damper device 9 includes a baffle 45 that opens and closes the first air passage 47. Further, the damper device 9 has a motor 42, and includes a drive unit 39 that operates the baffle 45 by the driving force of the motor 42. Further, the damper device 9 includes a lead wire 68 connected to the drive unit 39. The baffle 45 comes into contact with the rib 48, which is the peripheral edge of the first air passage 47, from above, and closes the first air passage 47. Further, in the state where the baffle 45 closes the first air passage 47, the contact portion between the baffle 45 and the rib 48 is arranged below the dam 69. The portion of the lead wire 68 located in the recess 81 in a plan view is arranged above the dam 69.

Therefore, in the refrigerator 100 according to the present embodiment, the water that has passed over the dam 69 travels through the groove for accommodating the lead wire 68 to the surface of the baffle 45 on the side of the baffle 45 that comes into contact with the rib 48 on the periphery of the first air passage 47. Adhesion can be suppressed more than before. Therefore, the refrigerator 100 according to the present embodiment can suppress the malfunction of the baffle 45 due to freezing as compared with the conventional case.

In the present embodiment, the damper device 9 for opening and closing the air passage for supplying cold air to the refrigerating chamber 1 has been described. However, other than the refrigerating chamber 1, there is a storage chamber whose set temperature is in the refrigerating temperature zone, and a damper device for opening and closing the air passage for supplying cold air to the storage chamber is also embedded in the partition wall constituting the lower surface of the storage chamber. May be installed. The above-mentioned effect can also be obtained by routing the lead wire connected to the drive unit of the damper device as described above.

1 Refrigerator room, 2 Ice making room, 3 Small freezer room, 4 Freezer room, 5 Vegetable room, 6 Left door, 7 Right door, 8 Partition plate, 9 Damper device, 10 Inside fan, 11 Cooler, 12 Defrost heater , 13 drain pan, 14 compressor, 15 fan grill, 16 control board, 17 chill chamber, 18 cases, 19 shelves, 20 pockets, 21 air passage parts, 22 air outlets, 23 air outlets, 24 air passages, 25 cases, 26 Upper case, 27 Lower case, 28 Upper case, 29 Lower case, 30 doors, 31 doors, 32 doors, 33 doors, 34 insulation, 35 partition parts, 36 partition parts, 37 partition parts, 38 temperature sensor, 39 drive unit , 40 frame part, 41 screw, 42 motor, 43 gear, 44 driving pin, 45 baffle, 46 sealing material, 47 first air passage, 48 rib, 49 connection part, 50 upper member, 51 lower member, 52 inner box , 53 Outer box, 54 Insulation parts, 55a 2nd air passage, 55b air passage, 56a air passage, 56b air passage, 57 air passage, 58 Sealing material, 59 Insulation parts, 60 cover, 61 Main body lead wire, 62 Storage part , 63 2nd sealant, 64 damper device ASSY, 65 opening, 66 lead wire, 67 lid, 68 lead wire, 68a 1st end, 68b 2nd end, 69 dam, 70 tape, 71 1st groove , 72 2nd groove, 73 3rd groove, 74 1st sealing material, 75 front side part, 76 1st heat insulating part, 77 2nd heat insulating part, 78 temperature sensor, 79 covering part, 80 air passage, 81 recess, 90 Housing, 91 cooler room, 92 machine room, 100 refrigerator.

Claims (5)

A storage room where the set temperature is in the refrigerating temperature range,
A part of the upper surface constitutes the lower surface of the storage chamber, and
A damper device that opens and closes the air passage that supplies air to the storage chamber,
With
The partition part is
Behind the portion constituting the lower surface of the storage chamber, a recess is formed in which the upper portion is open and the lower portion of the damper device is housed.
A dam protruding upward is provided in front of the recess.
The damper device is
A first air passage, which is a part of the air passage that supplies air to the storage chamber, is formed.
A baffle that opens and closes the first air passage,
A drive unit having a motor and operating the baffle by the driving force of the motor,
The lead wire connected to the drive unit and
Equipped with a,
In a state where the front Symbol baffle closes the first air passage, the contact portion between the peripheral portion of the said baffle first air passage is located below the dam,
The portion of the lead wire located in the recess in a plan view is a refrigerator arranged above the dam. A second air passage, which is a part of the air passage, is formed, and is provided with a heat insulating component that covers the damper device from above.
The lead wire includes a first end portion which is a side end connected to the drive portion and a second end portion which is an end portion opposite to the first end portion.
When looking at the lead wire from the first end to the second end,
The lead wire extends through the second air passage to the upper surface portion of the heat insulating component, and extends.
The refrigerator according to claim 1, wherein the lead wire arranged on the upper surface portion of the heat insulating component extends from the second air passage to the front end portion of the upper surface portion and is arranged along the front end portion. The heat insulating component is used as a groove.
The first groove formed in the inner wall of the second air passage and
A second groove formed on the upper surface portion of the heat insulating component and communicating with the first groove portion and the front end portion of the upper surface portion,
A third groove formed on the upper surface portion along the front end portion and communicating with the second groove, and a third groove.
With
The refrigerator according to claim 2, wherein the lead wire is arranged in the groove. A first sealing material that closes between the lead wire and the inner wall surface of the groove in at least a part of the first groove and the second groove.
A second sealing material that covers the first groove and the second groove from above,
The refrigerator according to claim 3. The refrigerator according to any one of claims 1 to 4, wherein the baffle comes into contact with the peripheral edge portion from above and closes the first air passage.

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