JP5350322B2 - refrigerator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a refrigerator increased in blast efficiency by a damper device and improved in energy saving performance. <P>SOLUTION: The refrigerator includes: a first frame which has a first opening for sending cold air to a first blast duct; a second frame which has a second opening for sending the cold air to a second blast duct; first and second opening/closing bodies for opening and closing the first and second openings, respectively; and a drive means which is provided between the first and second frames so as to drive the first and second opening/closing bodies. A first drive shaft is provided at one side of the first opening/closing body; a second drive shaft is provided at the other side facing one side of the first opening/closing body; and an upper end of an air blower is positioned at a location below an intersection point of rotational loci of the first and second opening/closing bodies and above lowermost ends of the rotational loci of the first and second opening/closing bodies. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  The present invention relates to a refrigerator provided with a damper device.

  Conventionally, in each refrigerator having a refrigerated temperature zone and a refrigeration temperature zone, the cold air heat-exchanged by the cooler is blown to each of the storage chambers by a blowing means. In order to control the flow rate of cool air to the door, an opening / closing damper device, so-called “twin”, which has two openings and operates an opening / closing body (for example, a baffle or a flap) provided in each opening by a driving source such as a motor. There is known a configuration that includes a “damper” (also referred to as “double damper”) and controls opening and closing of two opening / closing bodies of the damper device.

  As conventional techniques related to the damper device, techniques described in Patent Document 1 and Patent Document 2 shown below are known.

  Patent Document 1 discloses a configuration in which driving wheels for driving two open / close baffles are intermittent gears, and they are arranged on the same axis.

  Further, in Patent Document 2, when both the first flap and the second flap are fully opened, and the motor is rotated in the direction to close the first flap, only the first flap is closed, When the motor is rotated, only the second flap is closed, when the motor is rotated backward, the first flap is opened, and when the motor is further rotated backward, the second flap is opened. A configuration to perform is disclosed. That is, the order of opening and closing operations in the form of “first flap / second flap” is “open / open” → “close / open” → “close / close” → “open / close” → “open”. / Open ".

Japanese Patent No. 3445723 Japanese Patent No. 3814576

  However, in the damper device described in Patent Document 1 and Patent Document 2, when shifting from a fully open state in which both openings are open to a fully closed state in which both openings are closed, only one of them can be closed sequentially. Therefore, there is a problem that it takes a long time to fully close both openings.

  Moreover, when installing the damper apparatus of the said patent document 1 and the patent document 2 in a refrigerator, if the positional relationship with an air blower and a storage room is not considered, a storage space will reduce, Furthermore, a damper apparatus will be resistance and at the time of ventilation. There is a risk.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to obtain a refrigerator having improved energy-saving performance while improving air blowing efficiency with a damper device.

  In order to solve the above-described problems, the refrigerator of the present invention includes a plurality of storage chambers that are partitioned in the refrigerator main body and each store food, and a cooler that cools the plurality of storage chambers for heat exchange. A cooler storage chamber in which the cooler is provided, a blower that blows cool air heat-exchanged by the cooler to the plurality of storage chambers, a first air duct that blows cool air to the plurality of storage chambers, and A second air duct, and a damper device that controls air flow to the first air duct and the second air duct, and the damper device blows cool air to the first air duct. A first frame having one opening, a second frame having a second opening for blowing cool air to the second air duct, and a first frame for opening and closing the first opening and the second opening, respectively. A first opening / closing body and a second opening / closing body; Drive means provided between the first frame and the second frame for driving the first opening and closing body and the second opening and closing body, and a first side on the one side of the first opening and closing body. And the second drive shaft is provided on the other side opposite to the one side of the first opening / closing body, and the upper end of the blower is connected to the first opening / closing body and the second opening / closing body. It is located below the intersection of the rotation trajectories of the body and above the lowest end of the rotation trajectories of the first opening / closing body and the second opening / closing body.

  Further, the lower end of the blower is positioned behind the line connecting the front end of the damper device and the front end of the cooler, and the lower end of the blower is inclined so as to be positioned forward of the upper end. Features.

  The plurality of storage chambers are a refrigeration temperature zone chamber and a refrigeration temperature zone chamber provided below the refrigeration temperature zone chamber, the damper device being provided behind the refrigeration temperature zone chamber, and the first ventilation When the duct communicates with the refrigeration temperature zone, the second air duct communicates with the refrigeration temperature zone, and the first opening and closing bodies are opened, the second opening and closing The body is positioned in front of the first opening / closing body, and the first opening / closing body and the second opening / closing body guide the cold air from the blower to the first air duct and the second air duct, respectively. It is characterized by that.

  Further, when the first opening / closing body is opened, the blower is positioned in front of an extension line of the first opening / closing body.

  ADVANTAGE OF THE INVENTION According to this invention, while improving ventilation efficiency with a damper apparatus, the refrigerator with improved energy saving performance can be obtained.

It is a front external view of the refrigerator which concerns on embodiment of this invention. It is XX sectional drawing of FIG. It is a front view showing the structure in the store | warehouse | chamber of the refrigerator which concerns on embodiment of this invention. FIG. 3 is an enlarged explanatory view of a main part of FIG. 2. 1 is a perspective view illustrating an overall configuration of a damper device according to an embodiment of the present invention. 1 is a perspective view illustrating an overall configuration of a damper device according to an embodiment of the present invention. FIG. 6 is a YY sectional view of FIG. 5. FIG. 6 is a partial perspective view seen in the same direction as FIG. 5. FIG. 6 is a partial perspective view when fully closed as viewed in the direction of arrow T in FIG. 5. FIG. 6 is a partial perspective view when fully opened as viewed in the direction of arrow T in FIG. 5. FIG. 6 is a sectional view taken along the line U-U in FIG. 5. It is VV sectional drawing of FIG. It is ZZ sectional drawing of FIG. It is WW sectional drawing of FIG. It is the schematic which shows the positional relationship of the idler gear and intermittent gear in the damper apparatus which concerns on embodiment of this invention. It is an operation | movement chart which shows operation | movement of the conventional damper apparatus. It is a timing chart which concerns on the conventional damper apparatus of FIG. 16a. It is a state table | surface figure based on the conventional damper apparatus of FIG. 16a. It is an operation | movement chart which shows operation | movement of the twin damper by this invention. It is a timing chart regarding the damper apparatus which concerns on embodiment of this invention of FIG. 17a. It is a state table | surface figure regarding the damper apparatus which concerns on embodiment of this invention of FIG. 17a. It is an operation | movement chart which shows the operation | movement of the twin damper by the modification of this invention. It is a timing chart regarding the damper apparatus which concerns on the modification of this invention of FIG. 18a. FIG. 18B is a state table for the damper device according to the modification of the present invention in FIG. 18A. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention, and shows a closed / closed state. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention, and shows an open / closed state. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention, and shows a half-open / half-open state. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention, and shows a closed / open state. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention, and shows an open / open state. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention, and shows a half-open / half-open state. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention, and shows the state which the 2nd opening / closing body closed previously. It is a schematic diagram which shows operation | movement of the drive means of the damper apparatus which concerns on embodiment of this invention, and shows a closed / closed state. It is a timing chart which shows the operation | movement procedure at the time of the compressor stop in a refrigerator. FIG. 6 is a sectional view taken along line XX in FIG. 1 in the second embodiment. It is a schematic diagram explaining the positional relationship with the air blower and cooler when the twin damper provided with this invention in Embodiment 2 is integrated in the refrigerator. It is a figure explaining the positional relationship of a twin damper and an air blower by the principal part explanatory drawing of FIG. FIG. 38 is an explanatory diagram corresponding to a cross section taken along line AB of FIG. 37. FIG. 38 is an explanatory diagram corresponding to a cross section taken along line CB in FIG. 37.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

(Overall configuration of refrigerator)
FIG. 1 is a front outline view of the refrigerator of the present embodiment. FIG. 2 is an XX longitudinal cross-sectional view in FIG. 1 illustrating a configuration inside the refrigerator. FIG. 3 is a front view illustrating the configuration inside the refrigerator. FIG. 4 is an enlarged explanatory view of the main part of FIG. 2 and shows the arrangement of the cold air duct and the outlet.

  As shown in FIG. 1, the refrigerator 1 of this embodiment has the refrigerator compartment 2, the ice making room 3, the upper freezer compartment 4, the lower freezer compartment 5, and the vegetable compartment 6 from upper direction. As an example, the refrigerator compartment 2 and the vegetable compartment 6 are storage rooms in a refrigerator temperature zone of approximately 3 to 5 ° C. Further, the ice making room 3, the upper freezing room 4 and the lower freezing room 5 are storage rooms in a freezing temperature zone of approximately −18 ° C. In the refrigerator compartment 2, a chilled compartment 2d is provided. The chilled chamber 2d is a storage chamber having a temperature range of approximately 1 ° C.

  The refrigerating room 2 includes, on the front side, refrigerating room doors 2a and 2b with double doors (so-called French type) divided into left and right. The ice making room 3, the upper freezing room 4, the lower freezing room 5, and the vegetable room 6 include a drawer type ice making room door 3a, an upper freezing room door 4a, a lower freezing room door 5a, and a vegetable room door 6a.

  The refrigerator 1 has a door sensor (not shown) that detects the open / closed state of the door provided in each storage room, and a state in which each door is determined to be open for a predetermined time, for example, 1 minute or more. When it is continued, an alarm (not shown) for notifying the user and a temperature setting device (not shown) for setting the temperature of the refrigerator compartment 2 and the temperature of the upper freezer compartment 4 and the lower freezer compartment 5 are provided. Yes.

  As shown in FIG. 2, the outside of the refrigerator 1 and the inside of the refrigerator 1 are separated by a heat insulating box 10 formed by filling a foam heat insulating material (foamed polyurethane) between the inner box 10a and the outer box 10b. ing. Moreover, the heat insulation box 10 of the refrigerator 1 has a plurality of vacuum heat insulating materials 36 mounted thereon.

  In the refrigerator, the upper heat insulating partition wall 28 separates the refrigerator compartment 2 from the upper freezing chamber 4 and the ice making chamber 3 (see FIG. 1, the ice making chamber 3 is not shown), and the lower heat insulating partition wall. 29 separates the lower freezer compartment 5 from the vegetable compartment 6.

  A plurality of door pockets 32 are provided inside the refrigerator compartment doors 2a and 2b (see FIGS. 1 and 2). The refrigerator compartment 2 is provided with a plurality of shelves 37. By the shelf 37, the refrigerator compartment 2 is partitioned into a plurality of storage spaces in the vertical direction, and a chilled chamber 2d is provided in the lowermost storage space.

  As shown in FIG. 2, the upper freezer compartment 4, the lower freezer compartment 5, and the vegetable compartment 6 are respectively provided with storage containers 3b, 4b, 5b, 6b integrally with a door provided in front of each storage compartment. ing. The ice making room door 3a, the upper freezing room door 4a, the lower freezing room door 5a, and the vegetable room door 6a are each put on a handle portion (not shown) and pulled out to the front side, whereby the storage containers 3b, 4b, 5b, 6b can be pulled out.

  The chilled chamber 2d is provided with a chilled chamber door (not shown) that opens and closes the front opening. And in the state which opened the refrigerator compartment doors 2a and 2b, a storage container of the chilled chamber 2d can be pulled out by putting a hand on the handle part (not shown) of a chilled chamber door and pulling a chilled chamber door to the near side. It has become.

  As shown in FIGS. 2 and 3, the cooler 7 is provided in a cooler storage chamber 8 provided substantially at the back of the lower freezing chamber 5. A blower 9 is provided in the cooler storage chamber 8 and above the cooler 7. Air that has been cooled by heat exchange in the cooler 7 (hereinafter, low-temperature air that has been heat-exchanged by the cooler 7 is referred to as “cold air”) is blown by the blower 9 into the refrigerator compartment air duct 11, the vegetable compartment air duct 25, and the upper stage refrigeration. It is sent to the respective storage rooms of the refrigerator compartment 2, the vegetable compartment 6, the upper freezer compartment 4, the lower freezer compartment 5, and the ice making compartment 3 through the room air duct 12, the lower freezer compartment air duct 13, and the ice making compartment air duct not shown. It is done. Air blowing to each storage chamber is controlled by opening and closing the first damper device 20 and the second damper device 50.

  Here, the first damper device 20 is a so-called twin damper device having two openings. The 1st opening 20a controls the ventilation to the refrigerator compartment ventilation duct 11, and the 2nd opening 20b is a structure which controls the ventilation to the vegetable room ventilation duct 25. FIG.

  Incidentally, the air ducts to the refrigerator compartment 2, the ice making room 3, the upper freezer room 4, the lower freezer room 5, and the vegetable room 6 are provided on the back side of each room of the refrigerator 1 as indicated by broken lines in FIG. Yes.

  Specifically, when the first opening 20 a of the first damper device 20 is in the open state and the second damper device 50 is in the closed state, the cold air is provided in multiple stages through the refrigerator compartment air duct 11. 2c is sent to the refrigerator compartment 2.

  When the second opening 20b of the first damper device 20 is in the open state and the second damper device 50 is in the closed state, the cold air is sent from the outlet 6c to the vegetable compartment 6 via the vegetable compartment air duct 25.

  The cold air that has cooled the refrigerator compartment 2 returns from the return port 2e provided at the lower portion of the refrigerator compartment 2 to the lower right portion as viewed from the front of the cooler storage chamber 8 through the refrigerator compartment return duct 16. The return air from the vegetable compartment 6 returns from the return port 6d to the lower portion of the cooler storage compartment 8 via the vegetable compartment return duct 6e.

  When the second damper device 50 is in the open state, the cold air exchanged by the cooler 7 passes through the ice making chamber air duct and the upper freezer compartment air duct 12 (not shown) from the blower outlets 3c and 4c, respectively. Air is sent to the ice making chamber 3 and the upper freezing chamber 4. Further, the air is blown from the outlet 5 c to the lower freezer compartment 5 through the lower freezer compartment air duct 13. For this reason, said 2nd damper apparatus 50 is attached above the blower cover 56 part mentioned later, and makes the ventilation to the ice making chamber 3 mentioned above easy.

  In addition, the cold air that has cooled the upper freezer room 4, the lower freezer room 5, and the ice making room 3 returns to the cooler storage room 8 through the freezer return port 17 provided in the lower part of the lower freezer room 5.

  And in FIG. 4, it is the partition member 54 that forms the outlets 3c, 4c, 5c. The partition member 54 divides the freezing room 4, the ice making room 3 and the lower freezing room 5, and the cooler storage room 8.

  55 is a fan support member to which the internal fan 9 is attached. The blower support member 55 is provided and partitioned between the cooler storage chamber 8 and the partition member 54.

  The blower 9 is attached to the blower support member 55. A blower cover 56 covers the front surface of the blower 9. Between the blower cover 56 and the partition member 54, an ice making room air duct (not shown), an upper freezer compartment air duct 12, and a lower freezer room air duct 13 are formed. The upper part of the blower cover 56 forms a blowout port 56a in which the second damper device 50 is provided.

  The blower cover 56 includes a rectifying unit 56 b that covers the front surface of the blower 9. The rectifying unit 56b has a shape in which the vicinity of the center facing the blower 9 protrudes toward the blower 9 side. Thereby, the turbulent flow caused by the cold air blown out can be rectified to improve the cooling efficiency and to prevent the generation of noise and the like.

  Further, the blower cover 56 is provided between the partition member 54 and the rear wall of the upper freezer compartment air duct 12 and the lower freezer compartment air duct 13 so as to guide the cold air blown from the blower 9 to the outlets 3c, 4c, 5c and the like. Is forming.

  Further, the blower cover 56 also plays a role of blowing the cool air blown out by the blower 9 to the first damper device 20 side. That is, surplus cold air that does not flow to the second damper device 50 side provided in the blower cover 56 part flows to the first damper device 20 side via the refrigerator compartment duct 15 as shown in FIG. .

  And the cold air which passed through the cooler 7 is put into the storage room of both the freezing temperature zone room (the upper freezing room 4, the lower freezing room 5, and the ice making room 3) and the refrigeration temperature zone room (the refrigeration room 2 and the vegetable room 6). In the case of sending, most of the cool air is sent to the second damper device 50 side, and the remaining small amount of cool air is sent to the refrigerator compartment duct 15 side.

  Furthermore, the cold air led to the refrigerator compartment duct 15 is led to the refrigerator compartment air duct 11 when only the first opening 20a of the first damper device 20 is open. When only the second opening 20 b is opened, the vegetable room air duct 25 is led. When both the first opening 20a and the second opening 20b are opened, the air is guided to both the refrigerator compartment air duct 11 and the vegetable compartment air duct 25.

  Moreover, the 2nd opening 20b of the 1st damper apparatus 20 is good also as a structure guided not to the vegetable room ventilation duct 25 but to the chilled room 2d. In the case of this configuration, the temperature can be switched so that the chilled chamber 2d has an ice temperature zone (about -1 ° C) lower than the normal chilled temperature zone (about 1 ° C). In other words, the storage temperature zone can be selected by the user so that foods that do not want to be frozen, such as foods with high moisture content, are in the chilled temperature zone, and those that are stored frozen, such as meat and fish, are in the ice temperature zone. Therefore, it is possible to store the right material at the right temperature according to the food.

  In addition, said 1st damper apparatus 20 is attached to the rear part of the refrigerator compartment 2, as shown also in FIG.

  A defrost heater 22 is installed below the cooler 7, and an upper cover 53 is provided above the defrost heater 22 to prevent defrost water from dripping onto the defrost heater 22. It has been.

  The defrost water generated by the defrosting (melting) of the frost attached to the wall of the cooler 7 and the surrounding cooler storage chamber 8 flows into the water receiver 23 provided at the lower part of the cooler storage chamber 8. Later, it reaches an evaporating dish 21 disposed in a machine room 19 to be described later via a drain pipe 27 and is evaporated by heat of a compressor 24 and a condenser (not shown) to be described later.

  In addition, a cooler temperature sensor 35 attached to the cooler 7 is located in the upper right portion when viewed from the front of the cooler 7, a refrigerating room temperature sensor 33 is located in the refrigerating room 2, and a freezing room temperature sensor 34 is located in the lower freezing room 5. The temperature of the cooler 7 (hereinafter referred to as “cooler temperature”), the temperature of the refrigerator compartment 2 (hereinafter referred to as “refrigerator compartment temperature”), and the temperature of the lower freezer compartment 5 (hereinafter referred to as freezer compartment). (Referred to as temperature).

  Furthermore, the refrigerator 1 includes an outside air temperature sensor and an outside air humidity sensor (not shown) that detect a temperature and humidity environment (outside air temperature, outside air humidity) outside the refrigerator. Note that the vegetable room temperature sensor 33a may also be arranged in the vegetable room 6.

  A machine room 19 is provided on the lower back side of the heat insulating box 10. The machine room 19 contains a compressor 24 and a condenser (not shown). Is removed. Incidentally, in this embodiment, isobutane is used as a refrigerant, and the amount of refrigerant enclosed is as small as about 80 g.

  A control board 31 on which a CPU, a memory such as a ROM and a RAM, an interface circuit, and the like are mounted is disposed on the top surface side of the refrigerator 1. The control board 31 includes the above-described outside air temperature sensor, the outside air humidity sensor, the cooler temperature sensor 35, the refrigerating room temperature sensor 33, the freezing room temperature sensor 34, the door sensor for detecting the open / closed state of each storage room door, and the refrigerating room. A temperature setter (not shown) provided on the inner wall of the chamber 2 and a temperature setter (not shown) provided on the inner wall of the lower freezing chamber 5 are connected. And by the program previously mounted in the ROM, the ON / OFF of the compressor 24 and the control of the rotational speed, the first damper device 20 and the second damper device 50 are individually driven, which will be described later. Control, ON / OFF of the internal fan 9 and control of the rotational speed, control of ON / OFF of the external fan, rotational speed, etc., control of ON / OFF of the alarm for notifying the door open state described above, and the like are performed.

  Next, only the freezing temperature zone (the ice making chamber 3, the upper freezing chamber 4 and the lower freezing chamber 5) is cooled with the first damper device 20 closed and the second damper device 50 open. In this case, the cold air blown to the ice making chamber 3 through the ice making chamber air duct and the cold air blown to the upper freezer chamber 4 via the upper freezer chamber air duct 12 (see FIG. 2) To descend. And it flows like the freezing room return air shown by the arrow C in FIG. 4 with the cold air sent to the lower freezing room 5 through the lower freezing room ventilation duct 13 (refer FIG. 2). That is, it flows into the cooler storage chamber 8 from the lower front of the cooler storage chamber 8 via the freezer return port 17 arranged at the lower back of the lower freezer chamber 5, and a large number of fins are attached to the cooler piping 7a. Heat exchange is performed with the cooler 7 configured as described above.

  Incidentally, the width of the freezer compartment return port 17 is substantially equal to the width of the cooler 7.

  On the other hand, when the first damper device 20 is in the open state and the second damper device 50 is in the closed state, and only the refrigeration temperature zone room (refrigeration room or vegetable room 6) is being cooled, the refrigeration room 2 The return cold air flows from the side lower part of the cooler storage chamber 8 into the cooler storage chamber 8 through the refrigerator return duct 16 like the refrigerator return air indicated by arrow D in FIG. Exchange heat with the cooler 7.

  The cold air that has cooled the vegetable compartment 6 via the second opening 20b of the first damper device 20 is, as shown in FIG. 4, via the return port 6d (see FIG. 4), the cooler storage compartment 8. However, the air volume is smaller than the air volume circulating in the freezing temperature zone and the air volume circulating in the refrigerator compartment 2.

  As described above, the cooling air in the refrigerator 1 is switched by appropriately opening and closing each of the first damper device 20 and the second damper device 50.

(Configuration of damper device)
Next, an example of the configuration and operation of the first damper device 20 (twin damper device) will be described with reference to FIGS. FIG. 5 is a perspective view showing an example of the configuration of the first damper device 20. FIG. 6 is a view of FIG. 5 viewed from the back side of the drawing. 7 is a cross-sectional view in the YY direction in FIG.

  The first damper device 20 includes a first frame 63a that forms a first opening 62a and a second frame 63b that forms a second opening 62b. The first opening 62a and the second opening 62b are horizontally long and rectangular openings, and are formed and arranged on the first frame 63a and the second frame 63b, respectively, so as to be substantially in the same plane. The first frame 63a and the second frame 63b are made of resin, for example.

  Driving means 60 is disposed between the first frame 63a and the second frame 63b. The drive means 60 is housed in the case 60a and protrudes from the heights of the first frame 63a and the second frame 63b, and includes a drive system such as a motor and a reduction gear. A first drive shaft 61a is provided on the side of the drive means 60 that contacts the first frame 63a, and a second drive shaft 61b is provided on the side of the drive means 60 that contacts the second frame 63b. Output driving force respectively. Even when the case 60a and at least one of the first frame 63a and the second frame 63b are integrally formed, there is no particular limitation as long as the shape is the above.

  One end of the first opening / closing body 64a is connected to the first drive shaft 61a so as to be rotatable around the shaft. The other end of the first opening / closing body 64a is supported by a first support shaft 65a provided on the first frame 63a. The first opening / closing body 64a is provided to face the first opening 62a of the first frame 63a, and the first opening / closing body 64a rotates to open / close the first opening 62a. It is the structure to do. In other words, the first opening / closing body 64a is swingable around a rotation shaft connecting the first drive shaft 61a and the first support shaft 65a, and the rotation shaft is the first opening / closing body. It is arrange | positioned in the vicinity of the one side substantially parallel so that one side of the longitudinal direction of 64a may be followed.

  The first opening / closing body 64a is a resin-made plate-like first opening / closing plate 640a and a sealing member formed on one surface of the first opening / closing plate 640a with a flexible material such as urethane foam or polyethylene foam. A first sealing member 641a is provided.

  The basic structure of the second opening / closing body 64b is the same as that of the first opening / closing body 64a. Specifically, one end of the second opening / closing body 64b is connected to the second drive shaft 61b so as to be rotatable around the shaft. The other end of the second opening / closing body 64b is supported by a second support shaft 65b provided on the second frame 63b. The second opening / closing body 64b is provided opposite to the second opening 62b of the second frame 63b, and the second opening / closing body 64b rotates to open / close the second opening 62b. It is the structure to do. That is, the second opening / closing body 64b is swingable about a rotation shaft connecting the second drive shaft 61b and the second support shaft 65b, and the rotation shaft is the second opening / closing body. It is arranged substantially parallel to one side of the longitudinal direction of 64b and in the vicinity of the one side.

  The rotation axis of the first opening / closing body 64a and the rotation axis of the second opening / closing body 64b are provided in a positional relationship that does not intersect each other on the extension line. That is, the first drive shaft 61a and the second drive shaft 61b are respectively disposed on one side surface and the other side surface of the case 60a in which the drive unit 60 is accommodated. And the 2nd drive shaft 61b is provided in the other side opposite to one side of the longitudinal direction of the 1st opening-and-closing body 64a which provided the 1st drive shaft 61a. In other words, the first drive shaft 61a and the second drive shaft 61b are disposed so as to face each other with the shaft core shifted.

  5 to 7 show a state in which the first opening / closing body 64a and the second opening / closing body 64b are closed. The first frame 63a is provided with a first contact portion 66a protruding toward the first opening / closing body 64a along the inner periphery of the first opening 62a. And the 1st opening-and-closing body 64a contacts the extent to which the flexible 1st sealing member 641a elastically deforms with the 1st contact part 66a in a closed position. This suppresses the flow of cold air through the first opening 62a. When the motor is rotated, the first opening / closing body 64a rotates about 90 ° in the direction of the arrow (see FIGS. 5 and 7) via the first drive shaft 61a, and the first opening / closing body is indicated by 64a ′. When the first opening / closing body 64a rotates between the open position and the closed position, the cool air can pass through the first opening 62a in the open position, and the cool air in the closed position. It is the structure which blocks the flow of and closes.

  The second opening / closing body 64b has the same configuration and will not be described in detail.

(Configuration of drive means)
Next, an example of the configuration of the driving unit 60 will be described with reference to FIGS.

  8 to 10 are schematic perspective views showing the configuration of the driving means 60 as perspective views. 8 is a perspective view in the same direction as FIG. 5, and FIGS. 9 and 10 are perspective views from the T direction of FIG. 9 shows a state in which the first opening / closing body 64a and the second opening / closing body 64b are both closed, and FIG. 10 shows a state in which both are open.

  11 is a U-U cross-sectional view in FIG. 5, and FIG. 12 is a V-V cross-sectional view in FIG. 13 is a ZZ sectional view in FIG. 11, and FIG. 14 is a WW sectional view in FIG. FIG. 15 is an explanatory diagram showing the positional relationship between the idler gear 73 and the intermittent gear 76.

  The driving means 60 is accommodated in the case 60a. The driving means 60 includes a motor 70. A pinion gear 72 is provided on the output shaft 71 of the motor 70 and rotates with the driving of the motor 70 to output torque. The idler gear 73 is a reduction gear that is rotatably supported around an idler fulcrum 74. A gear 73a meshing with the pinion gear 72 is provided on the outer periphery of the idler gear 73, and the torque from the pinion gear 72 is transmitted while being reduced.

  The crank gear 77 is rotatably supported around a crank gear fulcrum 78. The crank gear 77 includes a gear 77a that meshes with an idler gear 73 on the outer periphery of the crank gear 77, and receives rotational torque from the idler gear 73 and rotates. The crank gear pin 77 b is provided eccentric from the crank gear fulcrum 78.

  The crank arm 79 is rotatable around the first drive shaft 61a. The driving means 60 is provided with a first shaft hole 60b (see FIG. 14), and the crank arm 79 is rotatably supported around the first shaft hole 60b. The first drive shaft 61a is fitted to the first opening / closing body 64a, and the first opening / closing body 64a (first opening / closing plate 640a, sealing member 641a) and the crank arm 79 are connected to rotate integrally. Move. That is, the first opening / closing body 64a has a longitudinal driving shaft of the first opening / closing body 64a (one end of the first opening / closing body 64a is pivotally supported by the first driving shaft 61a, and the other end is the Drive around one drive shaft 65a.

  The other end of the crank arm 79 opposite to the first drive shaft 61a forms a cylindrical fitting shaft 79c. The fitting shaft 79 c is rotatably fitted to a cylindrical bearing portion 85 extended from the driving means 60. Thus, the crank arm 79 is configured to be rotatably supported at both ends by the first shaft hole 60b and the bearing portion 85.

  The crank arm 79 is provided with a crank arm pin 79a that is eccentric from the first drive shaft 61a. One end 80a of the connecting rod 80 is rotatably fitted to the crank gear pin 77b, and the other end 80b is rotatably fitted to the crank arm pin 79a. That is, when the crank gear 77 rotates, the crank arm pin 79 a swings through the connecting rod 80, and the first opening / closing body 64 a opens and closes through the crank arm 79.

  The intermittent gear 76 is rotatably supported around an idler fulcrum 74 that is coaxial with the idler gear 73, and rotates upon receiving rotational torque from the idler gear 73. The structure of the idler gear 73 and the intermittent gear 76 will be described in detail with reference to FIG. 15. On the side of the idler gear 73 facing the intermittent gear 76, a fan-shaped protrusion 73b is provided around the rotation center in a range excluding the angle θ1. ing.

  A part of the intermittent gear 76 is provided with a first partial gear 76b only in a range where the intermittent gear 76 rotates by 90 °, for example. A portion of the intermittent gear 76 other than the first partial gear 76b is provided with a cylindrical portion 76c having a cylindrical shape. The outer diameter of the cylindrical portion 76c is equal to the diameter of the tooth tip portion of the first partial gear 76b. A sector-shaped projection 76d is provided in the range of the angle θ2 on the side where the first partial gear 76b is provided.

  Here, the fan-shaped protrusion 76d is fitted in a range of θ1 where the protrusion 73b of the idler gear 73 is not provided. Then, when θ1> θ2, the idler gear 73 is rotated in one direction so that one end surface 73b1 of the projection 73b contacts one end surface 76d1 of the projection 76d of the intermittent gear 76, and then the intermittent gear 76 is in contact with the idler gear 73. Rotate synchronously. Thereafter, when the idler gear 73 is rotated in the opposite direction, the range of the angle (θ1−θ2) is not in contact with the fan-shaped protrusion 76d and the protrusion 73b of the idler gear 73. As a result, the idle gears 73 rotate idly. Then, after the other end surface 76 d 2 of the projection 76 d of the intermittent gear 76 contacts the other end surface 73 b 2 of the projection 73 b of the idler gear 73, the intermittent gear 76 rotates in synchronization with the idler gear 73.

  In other words, the intermittent gear 76 rotates synchronously after stopping while the idler gear 73 rotates by an angle (θ1-θ2) in one direction. When the idler gear rotates in the other direction, the idler gear rotates while being rotated by the angle (θ1-θ2) and then rotates synchronously after stopping.

  As shown in FIGS. 8, 11 and 13, the idler gear 73 is provided with a fan-shaped recess 73c on the surface close to the inner wall surface of the case 60a, and the protrusion protruding inward on the inner wall surface of the case 60a. 81 is provided. The rotation angle range of the idler gear 73 is restricted to a predetermined angle θ3 by fitting the protrusion 81 inside the sector-shaped recess 73c.

  Next, as shown in FIG. 13, the output gear 75 is pivotally supported around the second drive shaft 61b. One end of the output gear 75 is rotatably fitted in a second shaft hole 60 c provided in the driving means 60. The second drive shaft 61b is fitted to the second opening / closing body 64b, and the second opening / closing body 64b (second opening / closing plate 640b, sealing member 641b) and the output gear 75 are connected and integrated. Rotate. In other words, the second opening / closing body 64b has a longitudinal driving shaft of the second opening / closing body 64b (one end of the second opening / closing body 64b is pivotally supported by the second driving shaft 61b, and the other end is the first of the frame 63). It is driven around a drive shaft (supported by the second support shaft 65b).

  The other end of the output gear 75 opposite to the second drive shaft 61b forms a cylindrical fitting shaft 75e. The fitting shaft 75e is rotatably fitted to a cylindrical bearing portion 84 extended from the driving means 60. Accordingly, the output gear 75 is configured to be rotatably supported at both ends by the second shaft hole 60c and the bearing portion 84.

  Part of the output gear 75 is provided with a second partial gear 75b. The second partial gear 75 b meshes with a partial gear 76 b provided on a part of the intermittent gear 76. The output gear 75 rotates by, for example, 90 ° in conjunction with the intermittent gear 76. On both sides of the partial gear 75b of the output gear 75, an arc-shaped first stopper 75c and a second stopper 75d are provided. The first stopper 75c and the second stopper 75d of the output gear 75 have an arc shape in which the second opening / closing body 64b is in a positional relationship with the cylindrical portion 76c of the intermittent gear 76 at the open position and the closed position. When the output gear 75 is rotated by approximately 90 °, which is a range where the partial gear 75b is engaged, the second opening / closing body 64b connected to the output gear 75 is rotated and opened / closed, and then the first stopper 75c or The second stopper 75d comes into contact with the cylindrical portion 76c of the intermittent gear 76 and is restricted from rotating.

  The 1st damper apparatus 20 is provided in the inside of the refrigerator compartment air duct 11 as shown in FIG. 3 or FIG. Therefore, the driving means 60 is required to be downsized, and in particular, it is desirable to reduce the thickness in the direction of the rotation axis and arrange the first opening / closing body 64a and the second opening / closing body 64b so as to narrow each other. As described above, when the motor 70 is rotated, the idler gear 73 rotates the first opening / closing body 64a around the first drive shaft 61a via the crank gear 77, the connecting rod 80, and the crank arm 79. This is a so-called crank mechanism. At the same time, the idler gear 73 is configured to rotate the second opening / closing body 64b around the second drive shaft 61b via the intermittent gear 76 and the output gear 75, and is driven by meshing of partial gears. It is an intermittent gear mechanism.

  Here, if the first drive shaft 61a and the second drive shaft 61b are arranged coaxially, the crank mechanism and the intermittent gear mechanism must be mounted vertically stacked in the rotation axis direction so as not to interfere with each other. Don't be. Then, the case 60a for storing the driving means 60 becomes undesirably thick in the direction of the rotation axis. Therefore, it is desirable to reduce the thickness of the driving means 60 by arranging the crank mechanism and the intermittent gear mechanism side by side.

  Therefore, as shown in FIGS. 9 to 12, the first drive shaft 61a and the second drive shaft 61b are provided at positions facing each other with the idler gear 73 interposed therebetween. Further, the crank gear 77 and the output gear 75 are arranged at positions almost opposite to the idler gear 73. A motor 70 is disposed between the crank gear 77 and the output gear 75 to engage the pinion gear 72 and the idler gear 73. Further, the connecting rod 80 and the crank arm 79 constituting the crank mechanism are arranged side by side so as not to interfere with the intermittent gear 76 and the motor 70 that rotate coaxially with the idler gear 73. That is, the first opening / closing body 64a and the second opening / closing body 64b are arranged so as to be driven around the respective rotation shafts (the first driving shaft 61a and the second driving shaft 61b), and the first opening / closing body The rotation axis of the body 64a and the rotation axis of the second opening / closing body 64b are not so-called concentric shafts but arranged differently. Thereby, in this embodiment, the drive means 60 is made thin. As shown in FIGS. 13 and 14, the thickness of the driving means 60 is substantially equal to the total thickness of the motor 70 and the pinion gear 72.

  Further, in a state where both the first opening / closing body 64a and the second opening / closing body 64b are closed, the side farthest from the first drive shaft 61a of the first opening / closing body 64a is the side of the second drive shaft 61b. The sides that are in the vicinity and are farthest from the second drive shaft 61b of the second opening / closing body 64b are staggered so as to be in the vicinity of the first drive shaft 61a. Further, if the opening directions are opposite to each other, the first opening / closing body 64a and the second opening / closing body 64b sandwich the driving means 60 in a state where the first opening / closing body 64a and the second opening / closing body 64b are closed. They are arranged on substantially the same plane. This configuration facilitates mounting and is suitable for downsizing.

  Further, the crank arm 79 and the output gear 75 are not coaxial and are rotatably supported around different axes. At the same time, one end is fitted into the first shaft hole 60 b provided in the driving means 60 and the other end is fitted into the cylindrical bearing portion 85. That is, since it can be supported by both ends, there is little backlash, and it is a structure that is rotationally supported with high precision. Therefore, both the first opening / closing body 64a and the second opening / closing body 64b are supported with high rotational accuracy, and can improve the sealing performance and suppress deformation and the like when the opening / closing body is enlarged. Is preferred.

(Twin damper operation)
Next, the operation of the first damper device 20 that opens and closes two openings according to the present embodiment, that is, a so-called twin damper will be described in comparison with the prior art.

  FIG. 16 represents the operation of the twin damper according to the prior art as an operation chart of FIG. 16a, a timing chart of FIG. 16b, and a state table of FIG. 16c, and represents a series of operations with different notations.

  First, how to read the operation chart of FIG. 16a will be described. The two open / close bodies provided in the twin damper have four states of closed / closed, open / closed, open / open, and closed / open, and a series of operations are performed in this order. When a series of operations are completed, the initial state is restored. Therefore, this operation is considered to be a 360 ° rotation operation for convenience, and the movement to each state is regarded as a rotation operation performed by a 90 ° operation. Can do. In addition, since this angle is for convenience, it does not indicate that any gear or motor is rotating at that angle as an entity, nor does it indicate that the operation amount of each operation is equal to each other. .

  The first opening / closing state of the first opening / closing body A is represented in the first quadrant of the two-dimensional graph with the opening / closing state of the second opening / closing body B being the Y axis. If the closed state is the origin (0, 0) and the movement amount to the open state is 1, the coordinates of the open / closed state where only the first opening / closing body A is open is (1, 0), and the second opening / closing The coordinates of the closed / open state where only the body B is open are (0, 1), the coordinates of the open / open state where both are open are (1, 1), and the state of the open / close body is (0, 0), It can be expressed as four coordinates (1, 0), (0, 1), (1, 1). A schematic diagram showing the open / close state of the open / close body is shown in the vicinity of each coordinate. The top dead center and bottom dead center will be described later.

  Next, the timing chart of FIG. 16b shows that the operation from 0 ° to 360 ° is taken as the time axis on the horizontal axis and the opening / closing operation is performed every 90 °. The state table of FIG. 16c shows both the open / closed state and the normal rotation and reverse rotation of the motor in a series of operations. One of the points where the rotation of the motor is rotated to the full and the rotation direction is switched is top dead. If the other point is the bottom dead center, this indicates that the motor is reciprocated between the top dead center and the bottom dead center by repeating forward and reverse rotations of the motor.

  The operation of the first opening / closing body and the second opening / closing body (flap) described in, for example, Patent Document 2 (Japanese Patent No. 3814576), which is a prior art, is first a closed / closed state in which both flaps are fully closed. When the motor is driven in the direction to open the first flap from (0, 0), the open / closed state (1, 0) is obtained in which only the first flap is opened. Through this state, the second flap is also opened to the open / open state (1, 1). Next, when the motor is rotated in the direction of closing the first flap, a closed / open state (0, 1) state in which only the first flap is closed is obtained. When the motor is further rotated, the second flap is closed to the closed / closed state (0, 0), and the initial state is restored.

  This operation corresponds to the operation chart of FIG. Expressing one movement from the bottom dead center at 0 ° represented by the closed / closed state (0,0) to the next state as an arrow parallel to the X or Y axis It is clear that the series of operations becomes four operations that go round four states counterclockwise in the figure.

  Here, in the prior art shown in FIG. 16a to FIG. 16c, either the first opening / closing body or the second opening / closing body performs the opening operation or the closing operation in the entire operation range, or the opening / closing operation is performed fully. Either to maintain the closed state. That is, there is no period in which both opening and closing bodies operate simultaneously. Therefore, in order to operate from the top dead center state where both are fully opened to the bottom dead center state where both opening and closing bodies are closed, two operations from 180 ° to 360 ° (0 °) are required. Two arrows in the chart are required.

  Next, the operation of the first damper device 20 according to the present invention will be described with reference to FIGS. FIG. 17a shows the operation of the first damper device 20 according to the present invention in the same chart as FIG. 16a, and FIG. 18a shows a modification thereof. 19 to 33 are schematic cross-sectional views for explaining a series of operations of an embodiment of the driving means 60 that realizes the operations shown in the chart shown in FIG. 17A.

  In the operation chart of FIG. 17a, the first opening / closing body and the second opening / closing body are closed / closed (0, 0), and only the first opening / closing body 64a is opened to open / closed (1,0). It becomes. Next, at the same time as the first opening / closing body is closed, the second opening / closing body is opened to the closed / open state (0, 1). Next, only the first opening / closing body 64a is opened to be in the open / open state (1, 1). Next, a series of operations is performed in which both the opening / closing bodies 64 are simultaneously closed to return to the closed / closed state (0, 0). In other words, when each operation is represented by an arrow, these are two parallel to the X axis and two opposite to the diagonal. By connecting these four arrows, four open / closed states are drawn with one stroke. Can be expressed as a series of operations.

  Here, the two arrows directed diagonally indicate that the first opening / closing body 64a and the second opening / closing body 64b perform opening / closing operations simultaneously. Here, from the open / open state (1, 1), both the opening / closing bodies 64 are simultaneously closed to be in a closed / closed state (0, 0) at once. As a result, from the fully open to fully closed state of both open / close bodies, one operation from the position of 270 ° to the position of 0 ° may be performed, and the operation for one arrow is sufficient, which is half that of the prior art shown in FIG. Only operating time is required.

  When this operation is represented by the timing chart of FIG. 17b, in a series of operations from 0 ° to 360 °, the first opening / closing body 64a reciprocates twice, and the second opening / closing body 64b intermittently opens and closes 1 It will be reciprocating. The ranges of 90 ° to 180 ° and 270 ° to 0 ° indicate the simultaneous operation range in which both the opening / closing bodies operate simultaneously. As in FIG. 16a, if the closed / closed state (0, 0) is the bottom dead center of the motor drive range, the closed / open state (0, 1) after performing the operation for two arrows from there. Becomes top dead center. In this configuration, the simultaneous operation of both the opening and closing bodies, that is, the time immediately after the arrow moves diagonally becomes the top dead center or the bottom dead center where the forward rotation or reverse drive by the motor 70 is completed. Details thereof will be described later.

  Next, in the modification shown in FIGS. 18a to 18c, the difference between the operation chart of FIG. 18a and the operation chart of FIG. 17a will be described. In FIG. 18a, instead of shifting from the open / open state (1, 1) to the closed / closed state (0, 0) diagonally, only the first opening / closing body 64a is closed and closed / open ( 0, 1), and then shifts to the open / closed state (1, 0) diagonally. At this time, the second opening / closing body 64b is closed simultaneously with the opening of the first opening / closing body 64a. Next, only the first opening / closing body 64a is closed to be in a closed / closed state (0, 0), and then both opening / closing bodies 64 are simultaneously opened to return to the open / open state (1, 1). .

  Next, the operation of the driving means 60 that performs the operation shown in FIG. 17 will be described with reference to FIGS. In FIG. 19 to FIG. 33, for the sake of explanation, a part of the portion on the back side of other parts is also overwritten. Moreover, the 1st opening 62a and the 2nd opening 62b are provided in the surface of the left side of illustration, and the 1st opening / closing body 64a and the 2nd opening / closing body 64b are typically shown with the thick line. The opening / closing body shows a state in which the substantially vertical state closes the opening and the substantially horizontal state opens.

  19 is the same as FIG. 12, the driving means 60 is in a state where both the first opening / closing body 64a and the second opening / closing body 64b are closed, that is, in the chart of FIG. ).

  The crank gear fulcrum 78, the crank gear pin 77b, and the crank arm pin 79a are substantially in a straight line, and a torque in the direction of the arrow is applied around the first drive shaft 61a via the connecting rod 80 to cause the first opening / closing body 64a to move. Closed. The cylindrical portion 76c provided in the intermittent gear 76 is fitted with the second stopper 75d of the output gear 75, and regulates the rotation of the output gear 75 and urges it in the direction of the arrow to form the second opening / closing body. 64b is held in a closed state.

  20 shows a state in which the motor 70 is driven from the state of FIG. 19 and the crank gear 77, the connecting rod 80, the crank arm 79, the pinion gear 72, and the idler gear 73 are rotated in the directions of the arrows, respectively. And the first opening / closing body 64a starts to open away from the opening 62.

  As the idler gear 73 rotates, the protrusion 73b rotates away from the end face 76d2 of the intermittent gear 76. Therefore, the intermittent gear 76 does not rotate from the state of FIG. 19, and the second opening / closing body 64b remains closed.

  FIG. 21 shows a position rotated further in the direction of the arrow as compared with FIG. In FIG. 21, the crank arm 79 further swings as the crank gear 77 rotates, and the first opening / closing body 64a continues to open. The crank gear pin 77b, the crank gear fulcrum 78, and the crank arm pin 79a are substantially in a straight line, and the crank arm 79 is pulled to the maximum, and the first opening / closing body 64a is fully opened around the first drive shaft 61a. Hold in position.

  That is, the state shown in FIG. 21 is the open / closed state (1, 0) in the chart of FIG. At this time, the protrusion 73 b of the idler gear 73 rotates in the direction of the arrow to a position where it contacts the end surface 76 d 1 of the intermittent gear 76.

  FIG. 22 shows a position rotated further in the direction of the arrow as compared with FIG. As the motor 70 rotates, the crank gear 77, the connecting rod 80, and the crank arm 79 move in the directions of the arrows, respectively, and the first opening / closing body 64a rotates in a closing direction around the first drive shaft 61a. The protrusion 73b is in contact with the end surface 76d1 of the intermittent gear 76, and the intermittent gear 76 rotates in synchronization with the idler gear 73. The partial gear 75b that is a part of the output gear 75 and the partial gear 76b that is provided on a part of the intermittent gear 76 are in a state immediately before meshing.

  FIG. 23 shows a position rotated further in the direction of the arrow as compared with FIG. The crank arm 79 is further swung, the first opening / closing body 64a is further closed, and the intermittent gear 76 is further rotated by the projection 73b of the idler gear 73 so that the end face 76d1 is further rotated, and the partial gear 76b and the output gear 75 are partially geared. Rotate the output gear 75 in mesh with 75b, rotate and open the second opening / closing body 64b around the second drive shaft 61b, and both the first opening / closing body 64a and the second opening / closing body 64b open about half. It will be half open.

  If the motor 70 is stopped in this state, the first opening / closing body 64a and the second opening / closing body 64b can maintain the half-open / half-open state. That is, the first opening / closing body 64a and the second opening / closing body 64b make the rotation angle when both the first opening 62a and the second opening 62b are both opened stand by in an acute angle state. The first drive shaft 61a and the second drive shaft 61b are disposed at positions facing each other with respect to the driven gear (idler gear 73), and the opening direction of the first opening / closing body 64a and the second opening / closing body 64b. The direction of opening is opposite to each other.

  Here, the first opening / closing body 64a and the second opening / closing body 64b function as a wind direction plate. Therefore, by arranging the structure in consideration of the opening direction of the first opening / closing body 64a and the opening direction of the second opening / closing body 64b, the air volume and the wind direction can be efficiently controlled while reducing the ventilation resistance. Can do.

  24 shows a position rotated further in the direction of the arrow as compared with FIG. 23, the first opening / closing body 64a is immediately before closing, and the second opening / closing body 64b continues to open.

  In FIG. 25, the crank gear 77 further rotates, the crank gear pin 77b, the crank gear fulcrum 78, and the crank arm pin 79a are almost in a straight line, and the first opening / closing body 64a is almost fully closed. On the other hand, the partial gear 75b of the output gear 75 finishes the meshing with the partial gear 76b of the intermittent gear 76, completes the opening operation, and reaches the fully opened position.

  Further, in the state of FIG. 26, the crank gear 77 further rotates, and the crank gear pin 77b, the crank gear fulcrum 78, and the crank arm pin 79a are substantially in a straight line. Then, the first opening / closing body 64a is held around the first drive shaft 61a in the fully closed position. The first stopper 75c of the output gear 75 further rotates in a state of being fitted to the cylindrical portion 76c that is a part of the intermittent gear 76, and holds the second opening / closing body 64b in an open state.

  The state shown in FIG. 26 is the closed / open state (0, 1) in the chart of FIG. 17A. Further, the idler gear 73 is in a position rotated fully in the clockwise direction in the figure, and is assumed to be in the position of “top dead center” in FIG.

  FIG. 26 is at the position of “top dead center”, and the pinion gear 72 of the motor 70 is rotated in reverse from FIG.

  In FIG. 27, when the motor 70 rotates in the reverse direction, the crank gear pin 77b of the crank gear 77 moves to the side away from the first drive shaft 61a. The crank arm pin 79 is rotated in the direction of the arrow through the connecting rod 80 and the crank arm pin 79a, and is rotated in the direction of opening the first opening / closing body 64a. Since the projection 73b of the idler gear 73 rotates away from one end face 76d1 of the intermittent gear 76, the idler gear 73 and the intermittent gear 76 are idled, and the intermittent gear 76 and the output gear 75 are moved from the open position shown in FIG. Instead, the second opening / closing body 64b is held in the open position.

  In FIG. 28, when the pinion gear 72 of the motor 70 is further rotated, the crank gear 77 is further rotated via the idler gear 73. Then, the crank gear 77, the connecting rod 80, and the crank arm 79 move to the same position as in FIG. 21, and hold the first opening / closing body 64a around the first drive shaft 61a in the fully open position. The protrusion 73b of the idler gear 73 rotates until it abuts against the other end surface 76d2 provided on the intermittent gear 76. In the state shown in FIGS. 26 to 28, the idler gear 73 and the intermittent gear 76 idle. The intermittent gear 76 and the output gear 75 do not move from the open position shown in FIG. 26, and the second opening / closing body 64b is held in the open position. The state of FIG. 28 shows the open / open state (1, 1) in the chart of FIG.

  Next, when the pinion gear 72 is further rotated as shown in FIG. 29, the crank gear 77, the connecting rod 80, and the crank arm 79 remain in the same positions as in FIG. It remains fully open. On the other hand, since the projection 73 d of the idler gear 73 is in contact with the other end surface 76 d 2 provided on the intermittent gear 76, the intermittent gear 76 rotates together with the idler gear 73. Then, the partial gear 76b of the intermittent gear 76 and the partial gear 75b of the output gear 75 start to mesh.

  If the motor 70 is further rotated to the state shown in FIG. 30, the crank gear 77, the connecting rod 80, and the crank arm 79 are rotated in the direction of the arrow, and the first opening / closing body 64a is moved to the first drive shaft 61a. Rotate around in a closing direction. The intermittent gear 76 rotates while the output gear 75 and the partial gears mesh with each other, and rotates the second opening / closing body 64b around the second drive shaft 61b in the closing direction.

  When the motor 70 is further driven, the state shown in FIG. 31 is reached, and the first opening / closing body 64a is continuously closed around the first drive shaft 61a. The second opening / closing body 64b continues to close around the second drive shaft 61b. Both the first opening / closing body 64a and the second opening / closing body 64b are in a half-open state during opening and closing. However, in the state of FIG. 31, the second opening / closing body 64b is almost closed, whereas the first opening / closing body 64a is opened to be larger than the second opening / closing body 64b.

  Next, the state of FIG. 32 is reached, and the first opening / closing body 64a further continues the closing operation. On the other hand, the intermittent gear 76 has finished meshing with the partial gear of the output gear 75, and the second opening / closing body 64b is set to the fully closed position. In the position of FIG. 32, the second opening / closing body 64b is already in the fully closed position, but the first opening / closing body 64a is in the middle of the closing operation.

  33, the crank gear 77, the connecting rod 80, and the crank arm 79 reach the same positions as in FIG. 19, and the first opening / closing body 64a is in the fully closed position. In the state shown in FIGS. 32 to 33, the idler gear 73 rotates the intermittent gear 76 via the end face 76d2. Engagement of the second partial gear 75b of the output gear 75 with the first partial gear 76b of the intermittent gear 76 is completed. Further, the second stopper 75d of the output gear 75 further rotates in a state of being fitted to the cylindrical portion 76c that is a part of the intermittent gear 76, and the second opening / closing body 64b is held in the closed state.

  That is, the output gear 75 does not move from the closed position shown in FIG. 32, and the second opening / closing body 64b is held in the closed position. The state shown in FIG. 33 is the same as the state shown in FIG. 19, and is a closed / closed state (0, 0) in the chart of FIG. 17, and the idler gear 73 is fully rotated in the counterclockwise direction shown in the figure. 17 is at the position of “bottom dead center”. That is, by performing the operations from FIG. 19 to FIG. 33, a series of operations for returning from the closed / closed, open / closed, closed / open, open / open to closed / closed state shown in the operation chart of FIG. It can be carried out. In other words, (1) a first mode in which the first opening / closing body 64a is driven to open the first opening 62a from a state in which the first opening 62a and the second opening 62b are closed; A second mode in which both the first opening / closing body 64a and the second opening / closing body 64b are driven so as to close the one opening 62a and open the second opening 62b; and (3) a state in which the second opening 62b is opened. A third mode in which the first opening / closing body 64a is driven to open the first opening 62a, and (4) a state in which the first opening 62a and the second opening 62b are both opened from the closed state. Thus, a fourth mode for driving both the first opening / closing body 64a and the second opening / closing body 64b is provided, and these modes are realized by a single driving means.

  The single drive means 60 is driven forward / reversely, and a first drive transmission means and a second drive transmission means for transmitting the driving force of the drive means 60 to the first opening / closing body 64a and the second opening / closing body 64b, respectively. Prepare. The first drive transmission means causes the first opening / closing body 64a to close after the opening operation while the driving means 60 rotates forward, and closes after the opening operation while rotating reversely. The second drive transmission means waits for a predetermined time without operating the second opening / closing body 64b while the driving means 60 is rotating forward, and then opens the opening / closing body. 64b is not operated and after waiting for a predetermined time, the closing operation is performed.

  Here, a drive gear 60, a driven gear (idler gear 73) for connecting the first drive transmission means and the second drive transmission means is provided, and the first drive transmission means includes a crank gear 77 and a crank arm 79. And a connecting rod 80 that connects the crank arm 79 and the crank gear 77, and meshes with the driven gear (idler gear 73) to rotate to transmit the driving force. The second drive transmission means idles in a predetermined angle range, and an intermittent gear 76 having a first partial gear 76b that rotates in contact with the driven gear (idler gear 73) outside the predetermined angle range; And a second partial gear 75b that is connected to the second opening / closing body 64b and meshes with the first partial gear 76b within a predetermined angle range to transmit a driving force.

  Here, in the state of FIG. 32, the second opening / closing body 64b is fully closed, so that the second sealing member 641b is pressed against the contact portion 66b provided in the second opening 62b to be compressed and deformed. The second opening 62b is sealed. Therefore, a large rotational torque for sealing the second opening / closing body 64 b is temporarily applied to the motor 70 via the output gear 75, the intermittent gear 76, and the idler gear 73.

  In the state shown in FIG. 33, the first opening / closing body 64a is fully closed, so that the first sealing member 641a is pressed against the contact portion 66a provided in the first opening 62a and compressed. The first opening 62a is deformed and hermetically sealed. Therefore, a large rotational torque for sealing the first opening / closing body 64 a is temporarily applied to the motor 70 via the crank arm 79, the connecting rod 80, and the crank gear 77. At this time, since the second opening / closing body 64b is already in the fully closed state, the cylindrical portion 76c of the intermittent gear 76 is in a state of being idled by being engaged with the second stopper 75d of the output gear 75, and intermittently. The rotational torque generated in the gear 76 is small.

  Here, in the case where the first opening / closing body 64a and the second opening / closing body 64b are closed at the same time, a large rotational torque for closing the two opening / closing bodies is applied to the motor 70 almost simultaneously. Therefore, it is necessary to use the motor 70 having a large output torque, and there arises a problem that the driving means 60 is increased in size and the noise at the time of driving the motor 70 is increased.

  Therefore, in this embodiment, after the second opening / closing body 64b is fully closed, the first opening / closing body 64a is closed with a time difference. In other words, the mode in which the first opening / closing body 64a and the second opening / closing body 64b are driven together is the driving of the other after the driving of either the first opening / closing body 64a or the second opening / closing body 64b is completed. Close the first opening 62a and the second opening 62b. That is, for the motor 70, the closing operation in which a large rotational torque for closing the second opening / closing body 64b is first applied is completed. Thereafter, a large rotational torque for closing the first opening / closing body 64a is applied in a light load state where the intermittent gear 76 idles. Thereby, a large rotational torque is not simultaneously applied to the motor 70, the motor 70 may be small, and there is an effect that the motor noise can be reduced with the downsizing of the driving means 60.

  Here, the “top dead center” in the closed / open state shown in FIG. 26 and the “bottom dead center” in the closed / closed state shown in FIG. 19 or 33 are the upper and lower limits of the operating range of the idler gear 73. It can be assumed that the position is. In any state, regardless of the operation direction, the simultaneous operation of both the first opening / closing body 64a and the second opening / closing body 64b is completed. As an example of the configuration for defining such an operating range, as described above with reference to FIGS. 11 and 13, the rotational angle range of the idler gear 73 is restricted to a predetermined angle θ3 by the fan-shaped recess 73c and the protrusion 81. This can be achieved.

  Here, when a stepping motor is used as the motor 70, an extra number of operation pulses is input as the rotation angle of the stepping motor more than the recess 73 a of the idler gear 73 abuts against the protrusion 81. The stepping motor simply steps out the extra operating pulse and does not rotate. Immediately after that, the idler gear 73 remains accurately at the position of “top dead center” or “bottom dead center”. That is, the position of the idler gear 73 can be accurately determined without the position detection means. Such a position fixing operation is referred to as “initialization”.

  In FIGS. 17 and 18, the dead point is when the simultaneous operation of both the opening / closing bodies 64 is completed as described above, that is, after the arrow indicating the operation moves diagonally. Since the top dead center and the bottom dead center mean that they are at both ends of the operating range of the mechanism, they do not necessarily specify the open / close state of the open / close body and the vertical positional relationship.

  By operating as described above, the first damper device 20 opens and closes the first opening / closing body 64a and the second opening / closing body 64b. That is, the first opening / closing body 64a is driven and opened in the first rotation direction around the first drive shaft 61a, and is driven and closed in the second rotation direction. On the other hand, the second opening / closing body 64b is driven and opened in the second rotation direction around the second drive shaft 61b, and is driven and closed in the first rotation direction. Thus, the rotation direction in the opening / closing operation of the first opening / closing body 64a and the second opening / closing body 64b is performed by rotating in directions opposite to each other.

  Next, an operation for opening and closing only the first opening / closing body 64a will be described. When the motor 70 is reversely rotated after the state shown in FIGS. 19 to 21 is changed from the closed / closed state to the open / closed state, the state shown in FIG. 19 is reached via FIGS. The second opening / closing body 64b remains in a closed state, and only the first opening / closing body 64a opens and closes and returns from the closed / closed state to the closed / closed state through the open / closed state. That is, if the operations from FIG. 19 to FIG. 21 are repeated, the opening / closing operation of only the first opening / closing body 64a can be repeated while the second opening / closing body 64b is closed.

  Further, when the motor 70 is reversed after the state shown in FIGS. 26 to 28, that is, the open / open state is changed from the closed / open state, the state shown in FIG. 26 is reached via FIGS. At this time, the second opening / closing body 64b remains open, and only the first opening / closing body 64a opens and closes to return from the open / closed state to the open / closed state through the open / closed state. That is, if the operations from FIG. 26 to FIG. 28 are repeated, the opening / closing operation of only the first opening / closing body 64a can be repeated with the second opening / closing body 64b open.

  Here, for example, as shown in FIG. 3 or 4, the first opening / closing body 64 a is connected to the refrigerator compartment air duct 11, and the second opening / closing body 64 b is connected to the vegetable compartment air duct 25. According to the above configuration (the operation from FIG. 19 to FIG. 21 or the operation from FIG. 26 to FIG. 28), only the refrigerator compartment air duct 11 is opened and closed with the vegetable room air duct 25 open or closed. be able to. Therefore, the balance of the amount of cool air to the refrigerator compartment 2 and the vegetable compartment 6 can be appropriately controlled, which is preferable.

  On the contrary, if the first opening / closing body 64a is connected to the vegetable room air duct 25 and the second opening / closing body 64b is connected to the refrigerating room air duct 11, the refrigerating room air duct 11 is opened or closed. In the state as it is, opening / closing control of only the vegetable room air duct 25 can be performed. Therefore, the balance of the amount of cold air to the vegetable room 6 and the refrigerator compartment 2 can be appropriately controlled, which is preferable.

  When the first opening / closing body 64a is connected to the refrigerator compartment air duct 11 and the second opening / closing body 64b is connected to a duct (not shown) for blowing air to the chilled chamber 2d, the refrigerator compartment air duct 11 is opened or opened. In a state of being closed, it is possible to control opening / closing of air to only the chilled chamber air duct.

  In the case of this configuration, the temperature can be switched so that the chilled chamber 2d has an ice temperature zone (about -1 ° C) lower than the normal chilled temperature zone (about 1 ° C). In other words, the storage temperature zone can be selected by the user so that foods that do not want to be frozen, such as foods with high moisture content, are in the chilled temperature zone, and those that are stored frozen, such as meat and fish, are in the ice temperature zone. Therefore, it is possible to store the right material at the right temperature according to the food. Therefore, the balance of the cool air flow rate to the chilled chamber 2d and the refrigerator compartment 2 can be appropriately controlled, which is preferable.

  In addition, in the case of this structure, the ventilation to the vegetable compartment 6 is provided with another damper device in the vegetable compartment ventilation duct 25 to control the amount of ventilation, or the return cold air from the refrigerator compartment 2 is used as the vegetable compartment ventilation duct 25. It is conceivable to use a configuration in which the air is fed into the vegetable compartment 6 and blown into the vegetable compartment 6. Other known techniques that can achieve the object of the present invention and have the same effects can be applied.

(Operation of compressor and damper device)
Next, an example of the operation when the compressor 24 is stopped in the refrigerator provided with the damper device will be described with reference to FIGS.

  FIG. 34 shows the blower 9, the first damper device 20 (twin damper) and the second from the time when the simultaneous cooling operation (hereinafter referred to as “FR operation”) of the freezer compartment and the refrigerator compartment is performed until the operation is stopped. 6 is a timing chart showing the open / closed state of the damper device 50 and the operation stop of the compressor 24.

  During the FR operation, both the first damper device 20 (twin damper) and the second damper device 50 are opened. In this state, the cool air exchanged by the compressor 7 by operating the compressor 24 is blown into the refrigerator compartment 2, the upper freezer compartment 4, and the lower freezer compartment 5 by driving the blower 9, and is cooled.

  When it is confirmed that the inside of the refrigerator compartment 2, the upper freezer compartment 4 and the lower freezer compartment 5 has been sufficiently cooled by the temperature sensor 34, a stop operation for stopping the compressor 24 and the blower 9 is performed. As the procedure at this time, (1) the blower 9 is stopped, (2) the first damper device 20 (twin damper) and the second damper device 50 are closed, and (3) the compressor 24 is stopped.

  When the compressor 24 is stopped simultaneously with the stop of the blower 9 when the operation is stopped, the first damper device 20 and the second damper device 50 are fully closed from the fully open state with both the blower 9 and the compressor 24 stopped. To work. Then, the operation sound of the damper device leaks out of the refrigerator 1 and becomes noise. Therefore, during the operation time of the damper device, that is, t (seconds), the blower 9 is already stopped, and the cool air is not sent to any of the upper freezer compartment 4, the lower freezer compartment 5, and the refrigerator compartment 2. Regardless, only the compressor 9 is wasted in order to cancel the operation sound of the second damper device 50 and the first damper device 20. Therefore, it is desirable to shorten the operation time of the damper as much as possible.

  In the first damper device 20 (twin damper) of the present embodiment, as described with reference to the operation chart of FIG. 17a and FIGS. 28 to 33, the first opening / closing body 64a and the second opening / closing body 64b are: From the open / open state, both are closed and the operation is closed / closed. For this reason, when the operation is stopped from the freezing room and refrigerating room cooling operations, only the time for operating only the compressor 24 is required. This can be shortened to ½ of the time required for the prior art shown in FIG. 16 to take two movements from the open / open state to the closed / closed state. Therefore, according to this embodiment, since the time for operating only the compressor 24 is reduced, a highly energy-saving refrigerator can be realized.

  As an example, it is assumed that there are 20 stop operations from the FR operation per day, and the time required for one operation of the damper from open to close or from close to open is 6 seconds. Then, it takes 12 seconds to operate only the compressor 24 if two operations are necessary. On the other hand, in one operation, 6 seconds are sufficient, and the operation time of the compressor 24 can be shortened by 20 times × 6 seconds = 2 minutes per day.

  Furthermore, since the operation time from fully open to fully closed can be shortened without increasing the rotational speed of the motor 70, a damper device with low operation noise and quick operation can be provided.

  Furthermore, since a time difference is provided in the closing operation of the first opening / closing body 64a and the second opening / closing body 64b, the rotational torque applied to the motor 70 can be reduced and realized by the small motor 70, and the driving means. There is an effect that the motor noise can be reduced together with the miniaturization of 60.

  Furthermore, as described with reference to FIGS. 17 and 19 to 33, in the first damper device 20 (twin damper) according to the present embodiment, the closed / closed state is the “bottom dead center” position in FIG. . Therefore, as described above, the initialization operation can be performed by rotating the motor 70 more excessively, and the rotation position of the stepping motor can be determined and positioned, which is more convenient.

  As described above, according to the present invention, the motor 70 is stopped and the positions of the first opening / closing body 64a and the second opening / closing body 64b are maintained in the half-open / half-open positions shown in FIGS. be able to.

  Here, the compressor 24 and the blower 9 are operated in a state where both the second damper device 50 and the first damper device 20 are opened, and the upper freezer compartment 4, the lower freezer compartment 5, the refrigerator compartment 2 and the vegetable compartment 6 are operated. In the case of performing the refrigeration / cooling operation for cooling both, the first damper device 20 is in a half-open / half-open state so that the amount of cold air passing through the second damper device 50 and the first damper device 20 is reduced. The ratio can be varied to set an appropriate air volume ratio. Thereby, overcooling etc. of the refrigerator compartment 2 can be prevented and energy saving property can be improved.

  As described above, according to the present invention, the first damper device 20 operates from the open / open state to the closed / closed state by one operation, so that only the compressor 24 is stopped when the freezer and refrigerator compartment cooling operations are stopped. Therefore, it is possible to obtain a refrigerator capable of ensuring energy saving performance while maintaining the food in the refrigerator 1 within a predetermined temperature range and maintaining the storage temperature of the food.

  Furthermore, the operation time from fully closed to fully open can be shortened without increasing the rotational speed of the motor, and a damper device with low operation noise and short operation time can be obtained.

  Furthermore, since the initialization, which is the position determining operation of the stepping motor, can be performed simultaneously with the operation in the closed / closed state, a damper apparatus with a reliable position determination and high operation accuracy can be obtained.

  Furthermore, by providing a time difference in closing the two opening / closing bodies, the load torque of the motor can be reduced and a small motor can be used, and the damper device can be reduced in size and noise.

  Furthermore, the ratio of the cool air flow rate passing through the first damper device 20 and the second damper device 50 can be varied and set to an appropriate air flow rate ratio to prevent the refrigerator compartment 2 from being overcooled. Thus, it is possible to obtain a refrigerator excellent in energy saving.

  Furthermore, since only the first opening / closing body 64a can be opened / closed with the second opening / closing body 64b open or closed, the amount of cold air blown into the refrigerator compartment 2 and the amount of cold air blown into the vegetable compartment 6 Alternatively, the amount of cool air blown into the refrigerator compartment 2 and the amount of cool air blown into the chilled chamber 2d can be controlled appropriately, and a refrigerator excellent in energy saving can be obtained.

  Furthermore, the crank arm 79 and the output gear 75 are arranged with their axis centers shifted from each other. That is, the first drive shaft 61a is provided on one side of the quadrangular first opening / closing body 64a. The second drive shaft 61b is provided on the other side of the first opening / closing body 64a and on one side of the quadrangular second opening / closing body 64b. The other side of the first opening / closing body 64a and the one side of the second opening / closing body 64b are arranged to be the same side. In addition, since they are pivotally supported around different axes rather than coaxially, both are fitted with shaft holes provided in the drive means, and the other end is fitted with a cylindrical bearing portion. Hold and support. For this reason, there is little backlash and it is the structure which is supported with high precision rotation. Therefore, both the first opening / closing body 64a and the second opening / closing body 64b are supported with high rotational accuracy. Thereby, while being able to improve a sealing performance, since bending deformation etc. when an opening-closing body is enlarged can be suppressed, it is a suitable structure for the enlargement of a damper.

  Next, Example 2 will be described with reference to FIGS. 35 is a cross-sectional view taken along the line XX of FIG. 1 in the second embodiment. FIG. 36 is a schematic diagram for explaining the positional relationship between the blower and the cooler when the twin damper provided with the present invention is incorporated in a refrigerator in the second embodiment. FIG. 37 is a diagram for explaining the positional relationship between the twin damper and the blower in the main part explanatory diagram of FIG. 36. 38 is an explanatory diagram corresponding to a cross section taken along line AB of FIG. 39 is an explanatory diagram corresponding to a cross section taken along line CB in FIG.

  Here, when the ventilation control of the storage room of the freezing temperature zone and the storage room of the refrigeration temperature zone is performed by the twin damper device, the damper device is installed behind the storage chamber of the freezing temperature zone. That is, the twin damper device is installed in a cooler chamber in which a cooler and a blower are housed.

  However, the height dimension of the cooler room is limited for the convenience of accommodating the cooler room within the height dimension of the freezer room. Then, it is necessary to arrange each component installed in the cooler chamber within a limited height dimension.

  As shown in FIG. 35, in this embodiment, the twin damper device 100 is installed in the cooler storage chamber 8. The twin damper device 100 controls air blowing to the refrigerating room 2 and the freezing temperature zone (at least one of the lower freezing room 5, the ice making room 3, and the upper freezing room 4). Thereby, the amount of cold air of the refrigerator compartment 2 and the freezing temperature zone room is controlled, and the temperature of each storage room is adjusted.

  By the way, in this structure, since the twin damper apparatus 100 is arrange | positioned in the area | region of a freezing temperature zone, dew condensation water may adhere to the twin damper apparatus 100 by the temperature difference with a refrigerator temperature zone. In addition, due to the relationship with the drainage of the condensed water, the arrangement of each component becomes a problem. The configuration according to the present embodiment will be described below based on this viewpoint.

  First, in FIG. 35, the basic configuration of the refrigerator is the same as that described in FIG. Therefore, the description of the same reference numerals as those in FIG. 2 is omitted.

  In FIG. 35, 100 is a twin damper device. The twin damper device 100 is installed in the upper part of the cooler storage chamber 8. The cool air exchanged by the cooler 7 in the cooler storage chamber 8 is blown by the blower 9 and the amount of blown air is controlled by the twin damper device 100. The difference from the case of FIG. 2 is that the storage chambers whose blast volume is controlled by the twin damper device 100 are the refrigerator compartment 2 and the lower freezer compartment 5.

  In FIG. 37, the twin damper device 100 includes a first frame 101a that forms a first opening 102a and a second frame 101b that forms a second opening 102b. The first opening 102a and the second opening 102b are horizontally long and rectangular openings, and are formed and arranged on the first frame 101a and the second frame 101b so as to be substantially in the same plane. The first frame 101a and the second frame 101b are made of resin, for example.

  A driving unit 60 is disposed between the first frame 101a and the second frame 101b. The drive means 106 is housed in the case 106a and protrudes from the heights of the first frame 101a and the second frame 101b, and includes a drive system such as a motor and a reduction gear. A first drive shaft 104a is provided on the side of the drive means 106 that contacts the first frame 101a, and a second drive shaft 104b is provided on the side of the drive means 106 that contacts the second frame 101b. Output driving force respectively.

  The rotation axis of the first opening / closing body 103a and the rotation axis of the second opening / closing body 103b are provided in a positional relationship that does not intersect with each other on the extension line. That is, the first drive shaft 104a and the second drive shaft 104b are respectively disposed on one side surface and the other side surface of the case 106a in which the driving means 106 is accommodated. And the 2nd drive shaft 104b is provided in the other side opposite to one side of the longitudinal direction of the 1st opening-and-closing body 103a which provided the 1st drive shaft 104a. In other words, the first drive shaft 104a and the second drive shaft 104b are disposed so as to face each other with the shaft core shifted. Note that the basic configuration and operation of the driving means are the same as those in the first embodiment, and thus the description thereof is omitted.

  Next, in FIG. 36, the relationship between the cooler, the blower, and the twin damper device in the second embodiment will be described.

  In the basic configuration, the blower 9 is disposed above the cooler 7 and the twin damper device 100 is disposed further upward. The blower 9 is installed in a state where the lower end 9b is positioned in front of the upper end 9a (left side in the drawing) and the whole is inclined. Thereby, the cold air heat-exchanged by the cooler 7 is blown to the upper twin damper device 100 side through the blower 9.

  Furthermore, the twin damper device 100 according to the present embodiment is arranged so that the first opening 102 a and the second opening 102 b are substantially horizontal with respect to the cooler 7. That is, the first frame 101a and the second frame 101b are provided so that both the first opening 102a and the second opening 102b face the cooler 7.

  The first opening / closing body 103a and the second opening / closing body 103b rotate until they are positioned substantially vertically downward when the first opening 102a and the second opening 102b are opened to the maximum. That is, the first opening / closing body 103a and the second opening / closing body 103b are installed so as to rotate to a rotation angle of about 90 degrees with respect to the first frame 101a and the second frame 101b, respectively.

  Here, in the configuration described above, if the drive shaft of the blower 9 is installed so as to be substantially vertical, when the first opening / closing body 103a and the second opening / closing body 103b are rotated to the open position, the first Condensed water adhering to the opening / closing body 103 a and the second opening / closing body 103 b may fall on the blower 9. Then, the condensed water adhering to the blower 9 gradually freezes and cannot operate.

  Therefore, the blower 9 in this embodiment is installed below the twin damper device 100 projection. Specifically, as shown in FIG. 36, the first opening / closing body 103a is disposed forward of the extension line of the first opening / closing body 103a (left side in the drawing) in a state where the first opening / closing body 103a is rotated to the open position.

  When controlling the ventilation to the refrigerator compartment 2 by the first opening / closing body 103a, as in the present embodiment, the blower 9 is positioned forward of at least the extension line when the first opening / closing body 103a is opened. The dripping of condensed water can be prevented. This is because the first opening / closing body 103a becomes a boundary between the refrigeration temperature zone and the freezing temperature zone, and a large amount of condensed water adheres to the first opening / closing body 103a due to a temperature difference.

  More preferably, the blower 9 is disposed so as to be located on the inner side of each extension line when the first opening / closing body 103a and the second opening / closing body 103b are opened. When the second opening / closing body 103b controls the ventilation to the refrigeration temperature zone, the twin damper device 100 is similarly installed in the environment of the refrigeration temperature zone, so there is little condensation on the second opening / closing body 103b, With this configuration, the reliability can be further improved.

  In addition, when the first opening / closing body 103a and the second opening / closing body 103b cannot be disposed on the inner side of the extension lines when the first opening / closing body 103a and the second opening / closing body 103b are opened due to the limitation of the size of the blower, as described above, The blower 9 is arranged so as to avoid the extension line.

  Further, in FIG. 35, a partition member 54 divides the freezing temperature zone chamber (the upper freezing chamber 4, the ice making chamber 3 and the lower freezing chamber 5) and the cooler storage chamber 8. The blower 9 is supported by a blower support member 55 between the cooler storage chamber 8 and the freezing temperature zone chamber. In this case, the twin damper device 100 and the blower 9 are located on the projection surface of the cooler 7. Thereby, the dimension of a depth direction can be made small and a storage space can be ensured large, and space efficiency can be improved.

  Next, in FIG. 36, the blower 9 is disposed above the lowest end R of the rotation range (trajectory) of the first opening / closing body 103a and the second opening / closing body 103b. Moreover, the upper end 9a of the air blower 9 is located below the intersection Q of the rotation locus of the first opening / closing body 103a and the second opening / closing body 103b. Furthermore, the lower end 9 b of the blower 9 is installed on the back side (right side in the drawing) from the straight line connecting the front end of the twin damper device 100 and the cooler 7. Thereby, a larger storage space can be secured. Further, by disposing the second opening / closing body 103b on the rear side of the extended line of the opening position of the second opening / closing body 103b, dripping of moisture from the second opening / closing body 103b can be prevented.

  37, the positional relationship between the twin damper device 100 and the blower 9 will be described. When the first opening / closing body 103a and the second opening / closing body 103b are opened, the blower 9 is a hatched portion when viewed from the front. Wrap with. That is, the inner corners of the first opening / closing body 103a and the second opening / closing body 103b wrap with the blower 9 when viewed from the front. Thereby, the cold air blown by the blower 9 is immediately guided to the first opening / closing body 103a and the second opening / closing body 103b, and a smooth cold air flow can be realized.

  Next, in FIG. 38, the details of the air blowing structure and control to the freezing temperature zone chamber will be described. The second opening / closing body 103b of the twin damper device 100 controls the temperature of the freezing temperature zone (the upper freezing room 4, the ice making room 3, and the lower freezing room 5) by adjusting the opening of the second opening 102b. . The second opening 102b opens and closes based on the value of a temperature sensor (not shown) installed in the refrigeration temperature zone chamber. When the temperature is higher than the set temperature, the second opening 102b is driven to the open position, Drive to the closed position.

  The partition member 107 is provided in front of the blower 9 and partitions the cooler storage chamber 8 and the freezing temperature zone. Further, a refrigeration temperature zone chamber air duct 108 is provided between the partition member 54 and the partition member 54. And the cold air heat-exchanged with the cooler 7 blows off from the freezing temperature zone room air duct 108 to the freezing temperature zone room through the air blower 9 and the damper apparatus 100, as shown by the arrow of FIG.

  Moreover, the part facing the air blower 9 of the partition member 107 has the rectification | straightening part 107a. After rectifying the cold air downstream of the blower 9 by the rectifying unit 107a, the air is smoothly blown to the twin damper device 100 side.

  Further, the second opening / closing body 103b is located on the partition member 107 side. In other words, the second drive shaft 104b is located in front of the upper end 9a of the blower 9 (left side in the drawing). Thereby, the cold air blown from the blower 9 is guided by the second opening / closing body 103b and flows to the refrigeration temperature zone chamber air duct 108. In addition, when the 2nd opening-and-closing body 103b is stopped in the open state slightly inclined, it can guide so that it may flow positively in the direction (refrigeration temperature zone room side) of the refrigerating temperature zone room air duct 108. That is, it is possible to obtain the same effect as when the refrigeration temperature zone chamber air duct 108 is extended to the vicinity of the blower 9.

  Next, in FIG. 39, the details of the air blowing structure and control to the refrigerator compartment 2 will be described. The first opening / closing body 103a of the twin damper device 100 controls the temperature of the refrigerator compartment 2 by adjusting the opening of the first opening 102a. The first opening 102a opens and closes based on the value of a temperature sensor (not shown) installed in the refrigerator compartment 2, and is driven to an open position when the temperature is higher than the set temperature, and closed when the temperature is lower than the set temperature. Drive to position.

  The cold air heat-exchanged by the cooler 7 passes through the blower 9 and the twin damper device 100 and is blown out from the refrigerating room air duct 109 toward the refrigerating room 2 as indicated by arrows.

  Further, the first opening / closing body 103a is located behind (on the right side in the drawing) the upper end 9a of the blower 9, and is in a range where the blower 9 is not located on the extended line when opened. Thereby, when the first opening / closing body 103a is opened, the dew condensation water is not dropped on the blower 9 but is dropped on the cooler 7 side.

  Moreover, when the 1st opening-and-closing body 103a opens, the cold air from the air blower 9 is ventilated smoothly to the refrigerator compartment air duct 109 side. That is, it is possible to obtain the same effect as when the refrigerator compartment air duct 109 is extended to the vicinity of the blower 9.

  The lower part of the blower 9 is connected to the partition member 107 and the upper part is connected to the rear wall of the cooler housing chamber. The connection of the upper part is connected to the rear wall of the cooler storage chamber at the portion of the case 106a when viewed from the front shown in FIG.

  The following effects can be obtained by the configuration of the present embodiment. A plurality of storage chambers that are partitioned in the refrigerator main body and each store food, a cooler in which cold air that cools the plurality of storage chambers is heat-exchanged, a cooler storage chamber in which the cooler is provided, and a cooler A blower that blows cold air heat-exchanged in the plurality of storage chambers, a first blower duct and a second blower duct that blow cool air to the plurality of storage chambers, and the first blower duct and the second blower duct. A damper device that controls air flow to the air duct, and the damper device blows cold air to the first frame having a first opening for blowing cool air to the first air duct and the second air duct. A second frame having a second opening, a first opening and closing body for opening and closing the first opening and the second opening, and a first frame and a second frame, respectively. The first opening / closing body and the second opening / closing body provided between A drive unit that moves, a first drive shaft is provided on one side of the first opening / closing body, and a second drive shaft is provided on the other side facing the one side of the first opening / closing body, Is located below the intersection of the rotation trajectories of the first opening and closing body and above the lowermost end of the rotation trajectories of the first opening and closing bodies. Thereby, while improving installation efficiency, cold air can be ventilated smoothly and the energy-saving performance can be improved.

  Further, the lower end of the blower is positioned behind the line connecting the front end of the damper device and the front end of the cooler, and the lower end of the blower is inclined so as to be positioned forward of the upper end. Thereby, the effective internal volume of a store room can be enlarged.

  The plurality of storage chambers are a refrigeration temperature zone chamber and a refrigeration temperature zone chamber provided below the refrigeration temperature zone chamber, and includes a damper device behind the refrigeration temperature zone chamber, and the first air duct is refrigerated. When communicating with the temperature zone chamber, the second air duct communicates with the refrigeration temperature zone chamber, and when the first opening / closing body and the second opening / closing body are opened, the second opening / closing body is the first opening / closing body. The first opening / closing body and the second opening / closing body guide the cool air from the blower to the first air blowing duct and the second air blowing duct, respectively. Thereby, cold air can be blown smoothly corresponding to the arrangement in the storage room, and energy saving performance can be improved.

  Further, when the first opening / closing body is opened, the blower is positioned in front of an extension line of the first opening / closing body. Thereby, it is possible to prevent the condensed water adhering to the opening / closing body from dripping onto the blower and freezing.

1 Refrigerator 2 Refrigerated room (refrigerated temperature zone)
2d chilled room 3 ice making room (freezing temperature room)
4 Upper freezer room (freezing temperature room)
5 Lower freezer compartment (freezing temperature zone)
6 Vegetable room (refrigerated temperature room)
20 First damper device (twin damper)
50 Second damper device 60 Driving means 60b First shaft hole 60c Second shaft holes 61a, 104a First drive shaft 61b, 104b Second drive shafts 62a, 102a First openings 62b, 102b Second Openings 63a, 101a First frames 63b, 101b Second frames 64a, 103a First open / close bodies 64b, 103b Second open / close bodies 65a First support shafts 65b Second support shafts 66a First contact portions 66b Second contact portion 70 Motor 71 Output shaft 72 Pinion gear 73 Idler gear 74 Idler fulcrum 75 Output gear 75e Mating shaft 76 Intermittent gear 77 Crank gear 78 Crank gear fulcrum 79 Crank arm 100 Twin damper device 107 Partition member 108 Refrigeration temperature zone chamber air duct (Second air duct)
109 Refrigerating room air duct (first air duct)

Claims (4)

A plurality of storage rooms that are compartmentally formed in the refrigerator body and each store food;
A cooler in which cold air for cooling the plurality of storage chambers is heat-exchanged;
A cooler storage chamber provided with the cooler;
A blower for blowing cool air heat-exchanged by the cooler to the plurality of storage chambers;
A first air duct and a second air duct that respectively blow cool air to the plurality of storage chambers;
A damper device for controlling air flow to the first air duct and the second air duct,
The damper device
A first frame having a first opening for blowing cool air to the first air duct, and a second frame having a second opening for blowing cold air to the second air duct;
A first opening and closing body for opening and closing the first opening and the second opening, respectively;
Drive means provided between the first frame and the second frame for driving the first opening and closing body and the second opening and closing body,
A first drive shaft is provided on one side of the first opening and closing body, and a second drive shaft is provided on the other side facing the one side of the first opening and closing body,
The upper end of the blower is from below the intersection of the rotation trajectories of the first opening / closing body and the second opening / closing body, and from the lowest end of the rotation trajectories of the first opening / closing body and the second opening / closing body. Is also located above.   2. The refrigerator according to claim 1, wherein a lower end of the blower is positioned on the back side of a line connecting a front end of the damper device and a front end of the cooler, and the lower end of the blower is positioned forward of the upper end. A refrigerator characterized in that it is inclined. 2. The refrigerator according to claim 1, wherein the plurality of storage chambers are a refrigeration temperature zone chamber and a refrigeration temperature zone chamber provided below the refrigeration temperature zone chamber, and the damper device is provided behind the refrigeration temperature zone chamber. ,
The first air duct is in communication with the refrigeration temperature zone chamber, and the second air duct is in communication with the refrigeration temperature zone chamber,
When the first opening / closing body and the second opening / closing body are opened, the second opening / closing body is positioned forward of the first opening / closing body, and the first opening / closing body and the second opening / closing body are located. The body guides the cool air from the blower to the first air duct and the second air duct, respectively.   The refrigerator according to claim 3, wherein when the first opening / closing body is opened, the blower is positioned in front of an extension line of the first opening / closing body.

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