JP6212319B2 - Cooling storage door device - Google Patents

Description

  The present invention relates to a wide-through type cooling storage door device.

  The thing of the following patent document 1 is known as an example of the door apparatus of this kind of cooling storage. In this case, a pair of left and right heat insulation doors are provided at the front opening of the storage body so as to be swingable and swingable, and packing is provided from the side edge of the back surface of each heat insulation door to the upper and lower side edges. A center seal having a close contact portion that can be in close contact with each other when the door is closed is arranged over the entire height near the corner on the side of the side facing the mating side of each heat insulating door. It is the structure that was established. The holding member is formed in a cylindrical shape, and a heater for heating the center seal is mounted in the holding member to prevent condensation on the surface of the center seal. Then, in order to protect the heater from being exposed and touching the heater, the upper and lower opening surfaces of the holding member are covered with a cap and fixed by screwing.

International Publication No. 2013/058257

By the way, depending on the usage mode of the cooling storage, etc., the heat insulating door may be opened and closed with an impact. In such a case, there is a concern that the screw may be loosened early and the cap may be removed. Was anxious.
The present invention has been completed based on the above circumstances, and an object thereof is to make it possible to reliably maintain the upper and lower opening surfaces of the holding member incorporating the heater in a closed state.

  In the cooling storage door device of the present invention, a pair of left and right heat insulating doors are provided in a front opening provided in a main body of the heat insulating box so as to be swingable and swingable and can be opened and closed. Packing is provided from the side edge on the swinging fulcrum side to the upper and lower side edges, and in the vicinity of the corner on the inner side of the side facing the mating side of each of the heat insulating doors, they are in close contact with each other when the door is closed. A center seal having a possible close contact portion is disposed over the entire height via a cylindrical holding member, and a heater for preventing condensation is mounted inside the holding member to heat the center seal. A first cap that is attached by screwing to the upper and lower opening surfaces of the holding member, and a second cap that is slidably mounted over the surface of the first cap. Has characteristics.

First, the first cap is attached to the upper and lower opening surfaces of the holding member by screwing, and the second cap covers the surface of the first cap and is slide mounted. Even if the screw that stops the first cap is loosened due to an impact force acting on the heat insulating door, the amount of looseness of the screw is restricted by the second cap covering, and the first cap is removed. Is avoided. As a result, the heater is prevented from being exposed to the outside.
Since the screw is covered with the second cap, dust is prevented from accumulating on the screw head and the like, which is preferable in terms of hygiene, and the appearance is excellent because the screw is hidden. .

The following configuration may also be used.
(1) The center seal has a leg portion fitted to a guide provided along the length direction of the holding member, and can be attached and detached in a slide form. A relief groove that can be inserted through the portion is cut out.
The center seal can be attached and detached while sliding with the first cap attached.

(2) The holding member is composed of a base that is fixed to a side surface of the heat insulating door with screws and a cover plate that is attached to the surface side of the base with a space therebetween, and the cover plate A stopper portion is provided on the back surface of the base plate so as to face the head of the screw mounted to attach the base.
If the screw that stops the base has been loosened due to external impact or vibration, the amount of looseness of the screw is regulated by the head hitting the stopper, and the screw is reliably prevented from being removed. Is prevented from coming off.

(3) The stopper portion is formed with a pressing portion that can elastically press the head portion of the screw.
Since the pressing portion always presses the head of the screw elastically, the screw is more securely prevented from loosening.

  (4) The insertion hole of the screw opened in the base of the holding member is formed in a long hole shape that is long in the front and back direction so as to adjust the position of the base along the front and back direction of the heat insulating door and screw it. In addition, a protrusion that can be crushed by the seat surface of the screw when the screw is fastened is formed at the hole edge of the insertion hole.

If the screw insertion hole is long and long in the front and back direction of the insulated door, the base is allowed to move in the same direction when impacts etc. are repeatedly applied to the insulated door after the screw begins to loosen. However, there is a risk that the loosening of the screw may proceed at an accelerated rate due to the frictional engagement with the screw seating surface.
In this configuration, since a protrusion is formed at the hole edge of the insertion hole so as to be crushed by the seat surface of the screw when the screw is fastened, an impact or the like acts on the heat insulation door after the screw is slightly loosened. As a result, when the base tries to move in the front and back direction of the insulated door, the head of the screw hits the protrusion that remains without being crushed, and the base is restricted from moving in the same direction. More loosening is avoided.

  According to the present invention, the upper and lower opening surfaces of the holding member incorporating the heater can be reliably maintained in the closed state.

Front view of the refrigerator according to Embodiment 1 of the present invention Partially cutaway perspective view seen from the back side of the insulated door Exploded perspective view of the center seal Cross sectional view Partial cross-sectional view in the closed state The perspective view which shows mounting | wearing operation | movement of a 1st cap. The perspective view which shows mounting | wearing operation | movement of a 2nd cap. A perspective view when the second cap is completely attached Partial plan view in the closed state Perspective view of first cap The perspective view which reversed the front and back of the 2nd cap The perspective view which shows mounting | wearing operation | movement of the 2nd cap which concerns on Embodiment 2. FIG. Plan sectional drawing of the arrangement part of the center seal concerning Embodiment 3 The perspective view which shows the state in which the base of the holding member which concerns on Embodiment 4 was adjusted and attached to one position. The perspective view which shows the state adjusted and attached to other positions The perspective view which shows the structure of the hole edge part of the penetration hole of a screw The perspective view which shows the structure of the hole edge part of the penetration hole when a screw is fastened

<Embodiment 1>
A first embodiment of the present invention will be described with reference to FIGS. In this embodiment, a wide-through horizontal refrigerator is illustrated.
The overall structure of the horizontal refrigerator will be described with reference to FIG. The refrigerator main body 10 is formed by a horizontally long heat insulating box whose front surface is opened, and is supported by legs 11 disposed on the bottom surface. The inside of the refrigerator main body 10 is a storage chamber 12, and a pair of left and right heat insulating doors 15 are attached to the front opening 13 serving as an entrance so as to be openable and closable. The pair of heat insulating doors 15 are supported so that the upper and lower ends of the outer vertical edges can be rotated about the vertical axis via hinges 16 and are close to the mutually adjacent ends on the upper edge of the front surface. Further, a handle 17 for opening / closing operation is provided. The front opening 13 is not provided with a vertical partition frame that partitions the front opening 13 left and right, and a center pillar-less, that is, a wide-through type door device is configured.

A machine room 18 is provided on the left side surface of the refrigerator main body 10 when viewed from the front, and an evaporator room (not shown) formed in a protruding manner from the storage room 12 is accommodated in the machine room 18. The chamber is equipped with an evaporator and an internal fan, and houses a refrigeration apparatus connected to the evaporator to form a refrigeration cycle.
When the refrigeration cycle is driven, cool air is generated in the vicinity of the evaporator, and the cold air is circulated and supplied into the storage chamber 12 by the internal fan, whereby the interior of the storage chamber 12 is cooled.

  Since the door device is of the wide-through type as described above, the seal structure at the time of closing the door is basically the vertical edge of the front opening 13 on the swing end side on the back surface of each heat insulating door 15. Packing 30 (see FIG. 2) mounted on the other three edges excluding the seal is sealed by being in close contact, and the vertical edges on the swinging end sides of both heat insulating doors 15 are along the vertical edges. The installed center seals 40 are sealed by being brought into close contact with each other. When both the heat insulating doors 15 are opened together, the front opening 13 can be fully opened with no partition.

Further, the structure of the heat insulating door 15, particularly the structure of the portion where the packing 30 and the center seal 40 are disposed will be described in detail.
The heat insulation door 15 is formed in a symmetrical shape, and as shown in FIGS. 2 and 4 and the like, a metal exterior plate 21 such as a stainless steel plate and a synthetic resin interior provided with a bulging portion 22A in the center. The outer shell 20 is formed by assembling the plate 22, and the outer shell 20 is filled with a heat insulating material (not shown) such as foamed resin. A packing mounting groove 25 having a rectangular shape is formed on the thin peripheral portion of the back surface of the heat insulating door 15.

The packing 30 is a magnet packing, is formed by extrusion molding of a synthetic resin material, and is used after being cut into a predetermined length. As shown in FIG. 4, the packing 30 has a mounting leg 33 protruding from the back side of a cylindrical packing body 31 whose interior is partitioned into a plurality of rooms, and a width on the surface side (upper side in the figure). A flat prism-shaped first magnet 35 is inserted into the first magnet chamber 32 located substantially in the center of the direction.
Four packings 30 are prepared corresponding to the four edges of the mounting groove 25 described above, and both ends of each packing 30 are cut at 45 degrees. The four packings 30 are mounted in the form of a rectangular frame over the entire circumference of the four edges while the mounting legs 33 are fitted in the mounting grooves 25 (see FIG. 2). A plurality of fins 36 project from the inner surface of each packing body 31 and are in close contact with the side surface of the bulging portion 22 </ b> A of the interior plate 22.

As shown in FIGS. 2 and 4, the center seal 40 is a holding member to be described later in the vicinity of the corner on the inner side of the side surface (hereinafter referred to as the opposing side surface 15 </ b> A) facing the counterpart on the swing end side of each heat insulating door 15. It is mounted in a form extending vertically through 55. The center seal 40 is made of synthetic resin and formed by extrusion, and is used after being cut to a length slightly shorter than the overall height of the heat insulating door 15.
The holding member 55 is made of synthetic resin, and will be described in detail later. The holding member 55 has the same length as the center seal 40, and the upper and lower edges thereof are the same small dimension as the upper and lower edges of the opposing side surface 15A. It is attached to the opposing side surface 15A in a retracted form.

The center seal 40 has a seal body 41 having a substantially portal-shaped cross section that opens to the outside of the cabinet (the lower side in FIG. 4). The seal body 41 is made of a soft resin, and a second magnet chamber 42 having a rectangular cross section is formed on a side portion facing the mating seal body 41, and a flat prismatic second magnet 43 is inserted. Has been.
The opposite side portion 44 of the seal body 41 is in close contact with the side surface of the vertically-oriented packing 30 disposed adjacently. The side portion 44 has an end on the outer side thereof bent toward the second magnet chamber 42, and a first leg 45 is formed at the bent end so as to be adjacent to the second magnet chamber 42. The first leg portion 45 is made of a hard resin, and an insertion groove 45A having a cross-sectional saddle shape is formed inside the first leg portion 45 so as to open to the outside of the warehouse.
A leg piece 47 having a predetermined width is formed so as to protrude from the outer end of the outer surface of the second magnet chamber 42 (the surface facing the opponent) to the outer side. The outer end of the leg piece 47 is bent inward, and a second leg 48 having a rectangular cross section made of hard resin is formed at the bent end.

From the end position of the seal body 41 on the inner side (upper side in FIG. 4) close to the vertical packing 30 on the swing end side, a cold air blocking lip portion 50 is formed to project. Each lip portion 50 has a shape in which the tip portion 50A is bent at an acute angle (for example, 75 °) toward the other side after projecting toward the inner side. The lip portion 50 is formed with a thin tip end, and when the door is closed, the tip portions 50A can overlap each other as shown in FIG.
Further, another fin portion 52 is formed so as to protrude from the same end portion position on the inner surface of the seal body 41. The overhanging end side of the fin portion 52 is a surface on the inner side of the first magnet chamber 32 in the vertical packing 30 (including the end portions of the horizontal packing 30 arranged on both upper and lower edges) on the swing end side. It is designed to be in close contact with each other.

The holding member 55 to which the center seal 40 is attached has the same length as the center seal 40 as described above, and the base 60 fixed to the opposing side surface 15A is spaced from the surface side of the base 60. The slide lid 70 is opened and attached.
The base 60 is fixed to the opposing side surface 15 </ b> A by being fastened with screws 61 at a plurality of locations (for example, two locations) extending in the vertical direction. In detail, as shown in FIG. 4, at the fastening position of the screw 61, the base 60 has an insertion hole 62 of the screw 61, and the opposing side surface 15A is formed with a screw hole 15B with burring. ing.

A heater holding portion 64 is formed on the side edge of the inner side of the base 60 over the entire height, and a fitting groove 65 for tightly fitting the heater 63 is formed in the heater holding portion 64 to be slightly narrow. The formed inlet 65A is opened toward the other side. The heater 63 is fitted in the fitting groove 65 in the radial direction from the inlet 65A, and the upper and lower ends of the heater 63 pass through the upper surface or the lower surface of the heater holding portion 64 as shown in FIG. A lead wire (not shown) that is turned outward (turned portion 63A) and connected to both upper and lower ends of the heater 63 is wired on the surface of the base 60.
From the inner surface of the heater holding portion 64, a guide portion 66 that fits tightly and slidably in an insertion groove 45A formed in the first leg portion 45 of the center seal 40 is formed to protrude. ing.

A slide lid 70 is detachably mounted on the surface side of the base 60 of the holding member 55. The slide lid 70 has a belt shape having the same length and the same width as the base 60, and an end edge portion on the outside of the warehouse is bent obliquely (inclined portion 70A).
A retaining rib 71 that enters the inlet 65A of the fitting groove 65 and presses the heater 63 is formed on the side edge of the inner side of the rear surface of the slide lid 70 (the surface facing the base 60). . In addition, a guide cylinder portion 72 having a rectangular cross section is formed in an approximately center width position on the back surface of the slide lid 70, and a second portion provided on the center seal 40 described above is formed in the guide cylinder portion 72. The leg portion 48 is slidably inserted through the slit groove 73.

At the positions of the inclined portion 70 </ b> A on the back surface of the slide lid 70 and the inner side of the guide tube portion 72, the hooks provided on the outer side edge of the base 60 and the side wall of the inlet 65 </ b> A of the fitting groove 65, respectively. A latching groove 75 that fits and latches the portion 67 is formed over the entire height.
As shown in FIG. 4, the slide lid 70 is configured such that both the latching portions 67 of the base 60 are fitted in the both latching grooves 75 and are slid along the latching portion 67 from above or below. As a result, the holding member 55 is formed in a flat and substantially rectangular tube shape with the outer edges being inclined edges.

  In other words, after the heater 63 is fitted in the fitting groove 65, the upper and lower ends thereof are bent to the outside of the heater holding portion 64 through the upper or lower surface of the heater holding portion 64. The lead wire connected to the portion is wired in the holding member 55. Both lead wires are wired to the central height position in the holding member 55, and then, as shown in FIG. 5, the lead pipe 68 opened in the base 60 is connected to the wiring conduit 26 embedded in the sectional door 15. It passes through to a predetermined power supply position.

  When the slide lid 70 is properly attached as described above, as shown in FIG. 4, the guide cylinder portion 72 that is formed on the back surface of the slide lid 70 fixes the base 60 to the opposing side surface 15 </ b> A. The head 61A of the screw 61 screwed as much as possible (for example, a substantially half region inside the warehouse) is opposed to the head 61A with a small interval s therebetween.

  In addition, when the slide lid 70 is normally attached, as shown in FIG. 6, the holding member 55 having a flat and substantially rectangular tube shape with both upper and lower end surfaces opened is formed. A cap C is provided to cover the opening surface. Since the curved portions 63A at both the upper and lower ends of the heater 63 face the opening surfaces at the upper and lower ends of the holding member 55, the cap C is used to protect the curved portion 63A of the heater 63. It is necessary to cover with.

Specifically, the cap C includes a first cap 80 and a second cap 90 both made of synthetic resin.
As shown in FIGS. 6 and 10, the first cap 80 covers the main body 81 so as to cover the upper and lower opening surfaces of the holding member 55 over the position of the upper edge or the lower edge of the opposing side surface 15 </ b> A of the heat insulating door 15. In detail, the main body 81 has a substantially rectangular cross section in which the outer edge of the storage is aligned with the holding member 55 and has an inclined edge, and faces the upper and lower end faces of the holding member 55; It is formed in a box shape in which the opposite side surface 15A and the opposite surface are opened.

  A mounting plate 82 having a predetermined width and extending along the upper surface or the lower surface of the heat insulation door 15 is formed on the outer surface (upper surface or lower surface) of the main body 81. The mounting plate 82 is formed with a recessed oval hole 84 having a long oval shape in the width direction (inside / outside direction), and an insertion hole 85 of a screw 83 having a slightly smaller hole at the center of the mounting hole 84. It is open.

On both side edges of the mounting plate 82, so-called first rails 86 are formed in which the protruding length gradually increases toward the outer surface side.
A stopper rib 87 is formed on the extending edge of the mounting plate 82 so as to rise over the entire width. Further, a locking hole 88 is formed on the front side edge of the seat hole 84 in the mounting plate 82 so as to protrude from the front side at a central position in the length direction.

  As shown in FIGS. 7 and 11, the second cap 90 has a substantially rectangular shallow dish shape so as to cover the first cap 80 including the upper and lower end surfaces of the center seal 40 and the end portions of the lateral packing 30. As shown by the arrow in FIG. 7, the heat insulating door 15 is mounted while being slid toward the facing side surface 15 </ b> A. Specifically, the second cap 90 is formed with an inclined surface 91 at a corner on the outer side of the surface on the near side in the mounting direction, on the back surface in the mounting direction, and on the right side when viewed from the near side in the mounting direction. A relief opening 92 is formed across the surface.

  A pair of second rails 94 extending along the mounting direction are arranged on the back surface of the outer surface plate 93 (upper surface plate or lower surface plate) of the second cap 90 so that the mounting plate 82 of the first cap 80 can be closely inserted. Are formed parallel to each other. A dovetail-like fitting with a large retraction amount toward the back side of the second cap 90 so that the dovetailed first rail 86 is fitted and fitted to the opposing surfaces of both the second rails 94. A joint groove 94A is formed.

In the area between the second rails 94 on the back surface of the outer surface plate 93 of the second cap 90, a substantially half area on the back side is cut into a thin wall to form a relief surface 95 in the form of being retracted one step. The relief surface 95 functions to avoid interference with the head 83A of the screw 83 to which the first cap 80 is fixed.
At the inner edge of the relief surface 95, a locking edge 96 is formed, which is retracted by a predetermined dimension, to which a stopper rib 87 provided on the extended end edge of the mounting plate 82 of the first cap 80 is fitted. .

  Further, the second cap 90 is formed on the mounting plate 82 of the first cap 80 when the second cap 90 is slid to the normal position at a position on the front side of the relief surface 95 on the back surface of the outer surface plate 93 of the second cap 90. A locking projection 97 that fits and locks into the formed locking hole 88 is formed. Note that the surface of the locking projection 97 that faces the edge of the locking hole 88 is formed as a forward tapered surface 97A, although it is relatively steep, and therefore the mounting direction with respect to the second cap 90 is the same as the mounting direction. When a tensile force of a predetermined level or more is applied in the opposite direction, the locking projection 97 can get over the hole edge before the locking hole 88 and come out.

  The heat insulation door 15 is manufactured in the following procedures, for example. After the wiring conduit 26 is disposed inside the exterior plate 21, the interior plate 22 is fitted on the back side of the exterior plate 21 to form the outer shell body 20, and the outer shell body 20 is made of foamed resin. The heat insulating door 15 is formed by foam filling the heat insulating material. As shown in FIG. 2, the packing 30 is mounted on the peripheral edge of the inner surface of the heat insulating door 15 in the form of a rectangular frame over the entire circumference of the four edges.

  Next, as shown in FIG. 3, the base 60 constituting the holding member 55 is applied to the opposing side surface 15 </ b> A of the heat insulating door 15, and as shown in FIG. 4, two places opened in the base 60 are inserted. The base 60 is fixed by screwing the screw 61 into the hole 62 and screwing into the screw hole 15B on the opposite side surface 15A. From this state, the heater 63 is closely fitted in the fitting groove 65 of the heater holding portion 64 provided vertically on the surface of the base 60, and the upper and lower ends of the heater 63 are connected to the heater holding portion 64. It is turned to the outside of the heater holding portion 64 through the upper surface or the lower surface. After that, the lead wire drawn to the surface side of the base 60 through the wiring conduit 26 is connected to the upper and lower ends of the heater 63.

Subsequently, the slide lid 70 is attached to the surface side of the base 60. As shown in FIG. 4, the slide lid 70 is configured such that both the latching portions 67 of the base 60 are fitted in the both latching grooves 75 and slid along the latching portion 67 from above, for example, as shown in FIG. As a result, a holding member 55 having a flat and substantially rectangular tube shape with an outer edge being an inclined edge is formed.
Accordingly, the retaining rib 71 provided on the back surface of the slide lid 70 enters the inlet 65A of the fitting groove 65 of the heater holding portion 64 over the entire height, and the heater 63 is prevented from coming off. Similarly, a guide cylinder portion 72 formed on the back surface of the base 60 is close to the head 61A of the screw 61 to which the base 60 is fixed (substantially half the inner region) with a small interval s. opposite.

Next, the center seal 40 is slidably attached to the holding member 55. The center seal 40 includes the first leg portion 45 and the second leg portion 48, the guide portion 66 of the base 60, and the guide of the slide lid 70, respectively. By fitting into the cylindrical portion 72 and sliding along the guide portion 66 and the guide cylindrical portion 72 from above, for example, as shown in FIG. Wear over. At this time, a fin portion 52 formed in close contact with the side surface of the packing 30 disposed adjacent to the seal body 41 and projecting from an end position on the side of the adjacent vertical packing 30 of the seal body 41 has the same packing. 30 and the inner side surface of the first magnet chamber 32 located at the end of the upper and lower lateral packings 30 are in close contact with each other.
At the same time, the second magnet 43 is inserted into the second magnet chamber 42 provided in the center seal 40 from above, for example. Plugs 49 (see FIG. 3) are fitted to the upper and lower ends of the second magnet chamber 42 to prevent them from coming off.

  Next, the cap C is attached to the upper and lower opening surfaces of the holding member 55. First, as shown in FIG. 6, the first cap 80 is mounted. Specifically, the main body 81 covers the upper and lower opening surfaces of the holding member 55 while accommodating the curved portion 63 </ b> A of the heater 63. The mounting plate 82 is applied to the end of the upper surface or the lower surface of the heat insulating door 15. From this state, the first cap 80 is fixed as shown in FIG. 7 by passing the screw 83 through the insertion hole 85 of the mounting plate 82 and screwing into the screw hole 15C on the upper surface or the lower surface of the heat insulating door 15.

Subsequently, the second cap 90 is mounted so as to substantially cover the first cap 80. Specifically, from the state where the pair of second rails 94 on the back surface of the second cap 90 is aligned with the first rails 86 on both side edges of the mounting plate 82 of the first cap 80, the second cap 90 is shown in FIG. As shown by the arrow line, it is pushed in while sliding toward the opposing side surface 15A of the heat insulating door 15. When the engaging edge 96 of the outer surface plate 93 of the second cap 90 hits the stopper rib 87 at the inner edge of the mounting plate 82 of the first cap 80, the pushing is stopped. At this time, the rear surface of the outer surface plate 93 of the second cap 90 is stopped. When the second cap 90 covers the first cap 80 as shown in FIG. 8, the retaining protrusion 97 is retained in the retaining hole 88 of the mounting plate 82 and retained. To be installed.
As described above, the heat insulating door 15 having the packing 30 and the center seal 40 mounted thereon is manufactured.

The door device of the present embodiment has the above-described structure, and when the left and right heat insulating doors 15 are closed, the packing 30 mounted on the inner surface of each heat insulating door 15, more specifically, a swing fulcrum. The vertical packing 30 arranged on the vertical edge on the side and the horizontal packing 30 arranged on the upper and lower horizontal edges are in close contact with each other over the entire periphery of the mouth of the front opening 13 of the storage chamber 12.
On the other hand, between the swing end sides of the left and right heat insulating doors 15, as shown in FIGS. 5 and 9, the second magnet chambers 42 of the left and right center seals 40 are connected to the side portions 44 of the seal body 41 and the second side. The leg piece 47 provided with the two leg portions 48 at the tip thereof is elastically deformed and sealed by being brought into close contact with a magnetic attraction force. Further, the front end portions 50A of the lip portions 50 protruding from the center seals 40 overlap with each other, and the inner side of the portion where the second magnet chambers 42 are in close contact with each other is covered by the lip portions 50.

The refrigerator is usually cooled by circulating and supplying cool air into the storage chamber 12 in the closed state as described above. On the other hand, in such a closed state, the leg pieces 47 provided on the center seals 40 are in contact with the outside air. Therefore, when the center seal 40 is cooled by the cool air inside the cabinet, there is a possibility that condensation occurs on the above surface. There is.
In this embodiment, as described above, the inside of the portion where the second magnet chambers 42 are in close contact with each other is covered with the two lip portions 50, and it is difficult for cold heat to be transmitted to the leg pieces 47. By energizing 63, the leg piece 47 is heated via the holding member 55 and the second leg portion 48, thereby preventing condensation on the surface of the leg piece 47.
When opening the door, the left and right heat insulating doors 15 may be opened together, or the left and right heat insulating doors 15 may be opened one by one.

According to this embodiment, the following effects can be obtained.
A heater 63 is accommodated in the holding member 55 to which the center seal 40 is mounted so as to heat the center seal 40. Due to the arrangement of the heater 63, the opening surfaces at the upper and lower ends of the holding member 55 are Since the curved portions 63A at both the upper and lower ends of the heater 63 face each other, it is necessary to cover with the cap C in order to protect the curved portion 63A of the heater. 80 is fixed by screws 83, and the second cap 90 is slidably mounted so as to cover the surface of the first cap 80.

Therefore, even if the screw 83 holding the first cap 80 is loosened due to an impact force acting on the heat insulating door 15 or the like, the first cap 80 is regulated by the second cap 90 restricting the amount of looseness of the screw 83. Is avoided. As a result, the curved portion 63A of the heater 63 is prevented from being exposed to the outside.
Further, since the screw 83 is covered with the second cap 90, dust is prevented from accumulating in the plus or minus groove for inserting the driver provided in the head 83A of the screw 83, which is preferable in terms of hygiene. In addition, since the screw 83 is concealed, the appearance is excellent.

In the present embodiment, the holding member 55 includes a base 60 that is attached to the opposing side surface 15 </ b> A of the heat insulating door 15 by screws 61 and a slide lid 70 that is attached to the surface side of the base 60 with a space therebetween. However, a guide tube portion 72 fitted with the second leg portion 48 of the center seal 40 is formed on the back surface of the slide lid 70 so as to protrude, and when the slide lid 70 is properly mounted, the guide guide described above is used. The cylindrical portion 72 is set to face the head 61A of the screw 61 to which the base 60 is fixed in close proximity with a small interval s.
Therefore, even if the shock 61 or the vibration acts on the heat insulating door 15 and the screw 61 that stops the base 60 is loosened, the head 61A hits the guide tube 72 and functions as a stopper, so that the amount of looseness of the screw 61 is regulated. Thus, the screw 61 is reliably prevented from being removed, and as a result, the base 60 is prevented from being removed.

<Embodiment 2>
FIG. 12 shows a second embodiment of the present invention.
In the second embodiment, the shape of the first cap 80X of the cap C that covers the upper and lower opening surfaces of the holding member 55 is improved. That is, a vertical relief groove 100 that allows the second leg portion 48 provided in the center seal 40 to be inserted is recessed in the side surface (side surface facing the other side) of the main body portion 81 of the first cap 80X. ing.

  According to this configuration, when the center seal 40 is to be replaced, the second leg 90 is removed while the first cap 80X is left attached after the second cap 90 is pulled out with a predetermined force or more. The center seal 40 can be pulled up and removed while passing through the relief groove 100, and conversely, it can be pushed in and attached. In short, the center seal 40 can be attached and detached while sliding with the first cap 80X attached.

<Embodiment 3>
FIG. 13 shows Embodiment 3 of the present invention.
In the third embodiment, the shape of the guide cylinder portion 72X provided on the rear surface of the slide lid 70, which functions as a stopper for the screw 61 that fixes the base 60 of the holding member 55, is improved. In other words, a pressing piece 105 having a predetermined width is formed so as to protrude from a corner portion on the outer side of the surface of the guide cylinder portion 72X facing the base 60. At the time of molding, the pressing piece 105 takes an oblique posture such that the overhanging end approaches the base 60 side as shown by a chain line in FIG.

  When the slide lid 70 is mounted at the regular position, the guide cylinder portion 72X is opposed to and close to the inner space of the head 61A of the head 61A of the screw 61 to which the base 60 is fixed. As shown by the solid line in the figure, the pressing piece 105 is elastically deformed, and its elastic force presses the region on the outside of the head 61A of the screw 61. That is, since the pressing piece 105 always presses the head 61A of the screw 61 elastically, the screw 61 is more reliably prevented from loosening.

<Embodiment 4>
Next, a fourth embodiment of the present invention will be described with reference to FIGS.
As shown in FIG. 5 according to the first embodiment, when the center seal 40 is disposed, the protruding end portion of the fin portion 52 formed on the center seal 40 is installed in the vertical direction. In order to prevent cold air leakage between the center seal 40 and the packing 30 so as to overlap and closely contact the inner surface of the first magnet chamber 32 at the end of the packing 30 or the upper and lower sideways packing 30. Yes. However, there is a situation that the packing 30 is likely to vary in manufacturing dimensions, for example, height dimensions.

Therefore, the center seal 40 is arranged along the inside / outside direction so that the fin portion 52 of the center seal 40 can be accurately overlapped with the first magnet chamber 32 of the packing 30 regardless of variations in the height dimension of the packing 30. The position can be adjusted and arranged. Specifically, in the structure of the portion for fixing the holding member 55 holding the center seal 40, particularly the base 60 to the opposite side surface 15A of the heat insulating door 15 with the screw 61, the insertion hole 62 of the screw 61 opening to the base 60 is By forming a long hole in the width direction (inside / outside direction) of the base 60, the fixing position of the base 60, that is, the holding member 55 is adjusted in the inside / outside direction, and the center seal 40 is positioned along the inside / outside direction. It can be adjusted.
Incidentally, FIG. 14 shows a case where the position of the holding member 55 and the center seal 40 is adjusted to the outermost side corresponding to the case where the height of the packing 30 is the minimum dimension Hmin, and FIG. Corresponding to the case where the height is the maximum dimension Hmax, the case where the position of the holding member 55 and the center seal 40 is adjusted to the innermost side is shown.

  As described above, when an impact or vibration is applied to the heat insulating door 15 as the heat insulating door 15 is opened and closed, the screw 61 holding the base 60 may be loosened. In particular, as described above, the insertion hole 62 of the screw 61 may be loosened. If the base 60 is in the shape of a long hole in the width direction of the base 60, the base 60 is allowed to move in the width direction when an impact or the like is repeatedly applied to the heat insulating door 15 thereafter, and the seating surface of the screw 61. There is a concern that the screw 61 is gradually loosened due to the frictional engagement.

As a countermeasure, in the present embodiment, as shown in FIG. 16, a plurality of longitudinal triangular ribs 110 are arranged at regular intervals around the hole edge of the insertion hole 62 having a long hole shape opened in the base 60. Open and formed. When the screw 61 is fastened, as shown in FIG. 17, the triangular rib 110 is crushed in the region 60X corresponding to the seating surface of the screw 61 (see reference numeral 110X).
As described above, when an impact or the like is applied to the heat insulating door 15 after the screw 61 is slightly loosened, the base 60 may move in the width direction as shown by the arrow in FIG. When 61A hits the triangular rib 110 remaining without being crushed, the base 60 is restricted from moving in the same direction, and as a result, the screw 61 is prevented from further loosening.

<Other embodiments>
The present invention is not limited to the embodiments described with reference to the above description and drawings. For example, the following embodiments are also included in the technical scope of the present invention.
(1) The assembling procedure illustrated in the above embodiment in the portion where the center seal is disposed is merely an example, and can be changed as appropriate.
(2) The close contact portion of the center seal is not limited to the magnet chamber exemplified in the above embodiment, but may be of another structure such as a lip formed so as to be able to overlap each other toward the other side.
(3) In the above embodiment, the case where the center seal is slidably mounted on the holding member has been illustrated. However, the present invention is not limited thereto, and other mounting means such as fitting from the front may be employed.
(4) The cover plate covering the opening surface of the holding member is not limited to the slide mounting, and other mounting means such as fitting from the front may be employed.

(5) If the sealability between the upper and lower end portions of the center seal and the end portions of the upper and lower lateral packings can be secured, the vertical packing located on the swing end side may be omitted.
(6) In the fourth embodiment, the triangular rib is exemplified as the crushable protrusion provided at the hole edge of the insertion hole. However, the rib may be a square or semicircular cross-sectional shape. Moreover, you may make it arrange many dot-shaped protrusions.
(7) The first leg portion and the second leg portion provided on the center seal may be provided with a rigidity that does not come off from the mating counterpart (guide portion and guide tube portion) when an external force is applied. Therefore, it may be formed of a soft resin with a countermeasure such as increasing the wall thickness.
(8) The present invention is not limited to the two-door horizontal refrigerator exemplified in the above embodiment, but a refrigerator having a different number of doors such as a four-door vertical refrigerator, a freezer, a refrigerator, and the like. It can be widely applied to all cooling storages equipped with wide-through type door devices.

  DESCRIPTION OF SYMBOLS 10 ... Refrigerator main body (storage main body) 13 ... Front opening part 15 ... Thermal insulation door 15A ... Opposite side surface 30 ... Packing 40 ... Center seal 42 ... 2nd magnet chamber (contact | adherence part) 45, 48 ... Leg part 55 ... Holding member 60 ... Base 61 ... Screw 61A ... Head 62 ... Insertion hole 63 ... Heater 64 ... Heater holding part 66 ... Guide part 70 ... Slide lid (lid plate) 72 ... Guide cylinder part (guide part; stopper part) 80, 80X ... First Cap 82 ... Mounting plate 83 ... Screw 86 ... First rail 90 ... Second cap 94 ... Second rail 100 ... Relief part 105 ... Pressing piece (pressing part) 110 ... Triangular rib (projecting part)

Claims (3)

A pair of left and right heat insulating doors are provided in a front opening provided in the storage body consisting of a heat insulating box so that it can swing open and close in a double-spread type,
Packing is disposed from the side edge on the swing fulcrum side on the back surface of each heat insulating door to the upper and lower side edges, and in the vicinity of the corner on the inner side of the side facing the mating side of each heat insulating door. A center seal having a close contact portion that can be in close contact with each other when the door is closed is disposed over the entire height via a cylindrical holding member,
And inside the holding member, a heater for preventing condensation is mounted to heat the center seal,
A first cap that is attached to the upper and lower opening surfaces of the holding member by screwing, and a second cap that is slidably mounted over the surface of the first cap ;
The center seal is slidably attachable to and detachable from a leg provided on a guide provided along the length direction of the holding member, and the leg is inserted into the first cap. A door device for a cooling storage, characterized in that a possible relief groove is cut out . A pair of left and right heat insulating doors are provided in a front opening provided in the storage body consisting of a heat insulating box so that it can swing open and close in a double-spread type,
Packing is disposed from the side edge on the swing fulcrum side on the back surface of each heat insulating door to the upper and lower side edges, and in the vicinity of the corner on the inner side of the side facing the mating side of each heat insulating door. A center seal having a close contact portion that can be in close contact with each other when the door is closed is disposed over the entire height via a cylindrical holding member,
And inside the holding member, a heater for preventing condensation is mounted to heat the center seal,
A first cap that is attached to the upper and lower opening surfaces of the holding member by screwing, and a second cap that is slidably mounted over the surface of the first cap ;
The holding member is composed of a base attached by screwing to the side surface of the heat insulating door, and a cover plate that is attached to the surface side of the base with a gap therebetween,
On the back surface of the lid plate, there is provided a stopper portion that is close to and opposed to the head of the screw that is mounted to attach the base.
A door part of a cooling storage box , wherein a pressing part capable of elastically pressing the head of the screw protrudes from the stopper part .   The insertion hole of the screw opened in the base of the holding member is formed in a long hole shape that is long in the front and back direction so as to position and adjust the base along the front and back direction of the heat insulating door. 3. The cooling storage box according to claim 2, wherein a protrusion that can be crushed by a seating surface of the screw when the screw is fastened is formed at a hole edge of the insertion hole. Door device.

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