JP6371151B2 - Cooling storage door device - Google Patents

Description

  The present invention relates to a door device for a cooling storehouse having a center seal with a magnet.

  As an example of this type of door device, one described in Patent Document 1 below is known. This is a structure in which a center seal disposed on the opposite side surfaces of a pair of heat insulating doors has a magnet built in on the opposite surface side and a leg portion that can be expanded and contracted on the back surface side. The part is attached to the side of the insulated door. When the heat insulation door is opened, the center seal is retracted by retracting the leg portion by being attracted by a magnetic plate attached to the side surface of the heat insulation door, and both the heat insulation doors are closed and each center seal is closed. When facing each other, each center seal advances toward the other side while extending the leg portion by the magnetic attraction force between the magnets, and a seal between the doors is taken by bringing the opposing surfaces into close contact with each other.

JP 2012-220167 A

In the conventional structure, since the magnetic plate is mounted on the side surface of the heat insulating door in order to hold the center seal in the retracted position, there is a discomfort for the structure to be complicated. Further, when the center seal is advanced, it is necessary to attract the magnets against the magnetic attractive force between the magnetic plates, so that a magnet having a large magnetic force is required, which tends to increase the cost as a whole. Therefore, further improvement was eagerly desired.
The present invention has been completed based on the above circumstances, and an object thereof is to provide a door device that realizes cost reduction.

  In the door device for the cooling storage 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 able to swing open and close in a double swing manner. A center seal made of an elastic material with a magnet is disposed on a side edge facing the side, and the center seal has a first surface and a first surface facing each other in parallel with each other. A second surface extending perpendicularly from the inner end of the container toward the heat-insulating door side, the extended end of which overlaps the back surface of the heat-insulating door, and a position before the extended end of the second surface. It is formed in a hollow shape having a third surface that protrudes toward the outside of the warehouse and has a protruding end fixed to the side edge of the heat insulating door. It is characterized by a magnet built-in.

When both heat insulating doors are closed, both magnets face each other and attract each other, so that each center seal is tilted and deformed with the third surface facing the other side, and the second surface has an extended end portion. While advancing toward the other side while maintaining the state of being overlapped on the back surface of the heat insulating door, the first surfaces approach each other and are in close contact with each other while maintaining a parallel posture. Thereby, after the seal between each center seal and the heat insulation door to which the center seal is mounted is secured, the space between the opposite side edges of both heat insulation doors is sealed.
The center seal of the present invention has a structure that is easily deformed forward and backward toward the other side. Therefore, if the magnetic force of the magnet is used as a reference, the allowable range of the distance between the center seals for normal adsorption increases, and specifically, the allowable range of dimensional errors and assembly errors of the center seal itself can be expanded. That is, since it can be set relatively rough, it can contribute to a reduction in manufacturing cost. In addition, secular change (deformation) associated with use can be dealt with over a long period of time, and the replacement time can be prolonged, leading to a reduction in so-called maintenance costs.
On the other hand, if the distance between the center seals is taken as a reference, the magnetic force of the magnet can be suppressed, and this can also reduce the cost. In addition, if the magnetic force of the magnet is suppressed, it is possible to obtain an attendant effect such that, when only one of the heat insulating doors is opened from the closed state, it is possible to prevent a problem that the other heat insulating door is opened. .
In total, the cost can be reduced.

The following configuration may also be used.
(1) In the hollow of the center seal, a deformation restricting portion is arranged in a form that enters from the side edge of the heat insulating door toward the interior direction.
If the center seal has a structure that tends to excessively move back and forth toward the other side, when both insulated doors are opened from the closed state, the center seal is elastically greatly deformed until the moment when the magnets are separated from each other. When returning to the original shape with the restoring elasticity at the moment, there is a possibility that a large vibration or sound may be generated, and there is a situation that it is not good from the viewpoint of durability by repeated large deformation.
On the other hand, in this configuration, when the center seal is elastically deformed toward the other side, when the third surface is tilted toward the other side, the tilt is restricted by hitting the deformation restricting portion, and the entire center seal is deformed. Since the amount is limited, the vibration and sound when restoring to the original shape can be kept small, the operability is excellent, and the durability of the center seal can be improved.

(2) The deformation restricting portion is formed in a form projecting from the side edge of the heat insulating door along the back surface of the magnet, and is a surface opposite to the side facing the magnet in the deformation restricting portion. An insertion groove having an enlarged inside is formed along the length direction, while a protruding leg of the third surface of the center seal is a latch leg that is inserted into the widened portion of the insertion groove. The part is formed.
Since the deformation restricting portion protrudes from the side edge of the heat insulating door and the latching leg portion of the projecting end of the third surface of the center seal is inserted into the insertion groove of the deformation restricting portion, A sufficient distance can be secured between the latch leg and the magnet housing, and extrusion can be performed properly.

(3) The outer end of the first surface of the center seal is extended to the outer side, and the extended end is fixed to the side edge of the heat insulating door.
By fixing the extending end extending from the first surface to the outside of the warehouse, the center seal is restricted from extending and deforming in the interior direction.

(4) On the surface facing the side edge of the mating heat insulating door at the side edge of the heat insulating door, an attachment groove that is open in the same surface and is expanded inward is formed along the length direction. The extending end of the first surface is formed with a fitting leg that can be fitted through the opening to the widened portion of the mounting groove.
The fitting leg portion provided at the extending end of the first surface of the center seal is pushed into the mounting groove in the width direction through the opening so as to be inserted. This can contribute to the simplification of the center seal mounting operation.

(5) The surface layer of the first surface of the center seal is formed of a material having a low friction coefficient.
When the door is closed, the frictional force between the center seals can be reduced. Therefore, even when one heat insulating door is opened with a relatively small operating force, it is possible to avoid a situation in which the other heat insulating door is opened with the other heat insulating door.

(6) The base end portion side of the second surface of the center seal is formed to be thicker than the extended end portion.
By thickening the base end portion of the second surface, a large restoring elasticity can be obtained, and when the heat insulating door is opened, the center seal can be reliably retracted to the original position. Therefore, for example, when the heat insulating door that has been opened one side is closed, the amount of interference of the center seal with the other heat insulating door is small, and the heat insulating door is automatically urged to the closed position and moved. That is, autism can be improved.

  ADVANTAGE OF THE INVENTION According to this invention, the door apparatus which implement | achieved cost reduction can be provided.

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 Cross section of center seal Partial cross-sectional view in the closed state Plan sectional drawing of the arrangement part of the center seal concerning Embodiment 2 Plan sectional drawing of the arrangement part of the center seal concerning Embodiment 3 Partial cross-sectional view in the closed state The top view which shows the modification of the molding shape of a center seal Plan sectional drawing of the arrangement part of the center seal concerning Embodiment 4 Partial cross-sectional view in the closed state The top view of the center seal concerning Embodiment 5 Enlarged view of XII section in Fig. 11 Plan sectional drawing of the arrangement | positioning part of the center seal | sticker concerning Embodiment 6. FIG. Plan view of the center seal mounting process with slide mounted Plan view during installation in the same width direction Plan view when mounting in the same width direction is completed The disassembled perspective view seen from the side surface side of the heat insulation door which shows the structure of the attachment part of the heater cap which concerns on Embodiment 7. FIG. The exploded perspective view seen from the back side of the heat insulation door Illustration of adhesive surface of caulking material Partial side view of insulated door

<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 insulating door 15 is formed in a symmetrical shape, and as shown in FIGS. 2 and 3, a metal exterior plate 21 such as a stainless steel plate and a synthetic resin interior plate provided with a bulging portion 22A in the center. The outer shell body 20 is formed by assembling 22 and the outer shell body 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. 3, 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 3, the center seal 40 has the holding member 60 in the vicinity of the corner on the inner side of the side surface (hereinafter referred to as the opposing side surface 15A) facing the counterpart on the swing end side of each heat insulating door 15. It is mounted in a form extending vertically. The center seal 40 is made of synthetic resin and formed by two-color extrusion, and is used after being cut to a length slightly shorter than the total height of the heat insulating door 15.

  The center seal 40 has a seal body 41 having a substantially square cylindrical shape. The seal body 41 is made of soft resin, and more specifically, the first surface 43 on the side facing the counterpart seal body 41 and the heat insulation door 15 side at right angles from the inner end of the first surface 43. A second surface 44 arranged toward (the right side of FIG. 3), a third surface 45 projecting at a right angle from the end of the second surface 44 on the heat insulating door 15 side toward the outside of the warehouse, A third surface 45 and a fourth surface 46 arranged to connect the outer end portions of the first surface 43 to each other are provided.

Said 4th surface 46 is formed in a waveform, and can be expanded-contracted in the direction (left-right direction of FIG. 3) which contacts / separates to the other party. On the end side of the fourth surface 46 that is close to the third surface 45, a leg 47 is formed so as to protrude toward the outside of the warehouse. The leg 47 is made of hard resin.
A second magnet chamber 48 is formed on the back surface side of the first surface 43 from a position slightly in front of the second surface 44 to the fourth surface 46, and a flat corner is formed in the second magnet chamber 48. A columnar second magnet 49 is inserted.

  Another fin portion 50 (corresponding to the extending end portion of the second surface 44 in the present invention) extends from the end portion of the second surface 44 intersecting the third surface 45, and the fin portion 50 is formed. The extending end of the first magnet chamber 32 overlaps and is in close contact with the vertical packing 30 on the swing end side (including the end portions of the horizontal packing 30 disposed on both upper and lower edges). It has become so. The contact width of the extended end of the fin portion 50 is such that the extended end of the fin portion 50 and the first magnet chamber 32 are still in close contact when the seal body 41 is deformed by a predetermined amount toward the other side as will be described later. It is the dimension which can maintain a state.

  From the end of the second surface 44 of the seal body 41 intersecting with the third surface 45, a lip portion 52 for blocking cold air is also formed protruding from the inside of the refrigerator. Specifically, the lip portion 52 has a shape in which, after protruding toward the inner side, the tip portion is bent at an acute angle (for example, 15 °) toward the other side. When the door is closed, as shown in FIG. 4, the tip portions of both lip portions 52 can be overlapped with each other.

  The holding member 60 to which the center seal 40 is attached has the same length as the center seal 40, and as shown in FIG. 3, a base 61 fixed to the opposing side surface 15A with a screw 62, and the base 61 It is comprised from the slide lid 65 attached to the surface side of this at intervals. The slide lid 65 is attached by fitting the latching grooves 66 provided at two locations inside and outside the backside of the slide lid 65 into the latching portions 63 provided on the base 61, and sliding from above or below. It can be assembled into a flat cylindrical shape that is long in the inside and outside direction.

  A mounting groove 67 through which the leg 47 of the center seal 40 is slidably inserted is formed on the inner wall surface of the base 61 of the holding member 60. Further, a heater holding groove 68 is formed at a corner inside the holding member 60, and a heater 69 for preventing condensation is inserted. Note that lead wires connected to the upper and lower ends of the heater 69 are wired in the holding member 60, and both lead wires are embedded in the sectional door 15 from the outlet 61 </ b> A opened in the base 61. 26 is routed to a predetermined power supply position.

  An example of the mounting procedure of the center seal 40 will be described again. The base 61 constituting the holding member 60 is applied to the opposing side surface 15A of the heat insulating door 15 and fixed by screws 62, and the heater 69 is installed in the heater holding groove 68. After being inserted, the slide lid 65 fits both the latching portions 63 of the base 61 into the both latching grooves 66 and slides along the latching portion 63 from above, for example, as shown in FIG. The holding member 60 is formed on the surface side of the base 61 with a predetermined interval, and as a result, a holding member 60 having a flat and substantially rectangular tube shape with an outer edge being an inclined edge is formed. The heater 69 is buried in the corner inside the cabinet.

  Next, the center seal 40 is slidably mounted on the holding member 60. The center seal is formed by fitting the leg portion 47 into the mounting groove 67 of the base 61 and sliding it along the mounting groove 67 from above, for example. As shown in FIG. 2, it is mounted over the entire height so as to generally follow the inner surface of the holding member 60. At this time, the third surface 45 of the seal body 41 is brought into close contact with the side surface of the packing 30 disposed adjacent thereto, and the fin portion 50 formed extending from the second surface 44 of the seal body 41 includes the packing 30 and The first magnet chamber 32 located at the end of the upper and lower side packing 30 is closely attached to the inner surface of the first magnet chamber 32 with a predetermined width.

At the same time, the second magnet 49 is inserted into the second magnet chamber 48 provided in the center seal 40 from above, for example. Plugs (not shown) are fitted to the upper and lower ends of the second magnet chamber 48 to prevent the second magnet chamber 48 from coming off. Subsequently, the cap 70 is attached to the upper and lower opening surfaces of the holding member 60 as shown in FIG.
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 FIG. 4, the second magnets 49 face each other and attract each other, so that each center seal 40 has a fourth surface 46. The third surface 45 is deformed to be extended and tilted and deformed toward the other side, and the second surface 44 advances toward the other side while maintaining the state in which the fin portion 50 is superimposed on the first magnet chamber 32. However, the first surfaces 43 approach each other while maintaining a parallel posture and are in close contact with each other. Thereby, the seal between the center seals 40 and the heat insulating doors 15 to which the center seals 40 are attached is secured, and the gap between the opposite side edges of the heat insulating doors 15 is sealed.
Further, as shown in FIG. 2, the end portions of the second surface 44 of the center seal 40 projecting upward and downward of the lip portion 52 are in close contact with the upper and lower rims of the front opening 13, and the both heat insulating doors 15 face each other. The gap between the side edges is sealed including the upper and lower portions.

Moreover, the front ends of the lip portions 52 formed to protrude from the center seals 40 overlap with each other, and the inner side of the portion where the second magnet chambers 48 are in close contact with each other is covered with the lip portions 52.
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 particularly extended fourth surface 46 of each center seal 40 is in contact with the outside air. Therefore, when the center seal 40 is cooled by the cool air inside the cabinet, condensation can occur on the above surface. There is sex.
In this embodiment, as described above, the inside of the portion where the second magnet chambers 48 are in close contact with each other is covered with the two lip portions 52, and it is difficult for cold heat to be transmitted to the fourth surface 46. By energizing the heater 69, the fourth surface 46 is heated via the holding member 60, and condensation on the surface of the fourth surface 46 is prevented.
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.

  The center seal 40 (seal main body 41) of the present embodiment has a structure that is easily deformed forward and backward toward the other side. Therefore, if the magnetic force of the second magnet 49 is used as a reference, the allowable range of the distance between the center seals 40 for normal adsorption increases, and specifically, the tolerance of the dimensional error and assembly error of the center seal 40 itself. Since the range can be widened, that is, it can be set relatively rough, it can contribute to the reduction of the manufacturing cost. In addition, secular change (deformation) associated with use can be dealt with over a long period of time, and the replacement time can be prolonged, leading to a reduction in so-called maintenance costs.

On the other hand, if the distance between the center seals 40 is taken as a reference, the magnetic force of the second magnet 49 can be suppressed, thereby reducing the cost. In addition, if the magnetic force of the second magnet 49 is suppressed, it is possible to prevent the problem of opening to the other heat insulating door 15 when only one heat insulating door 15 is opened from the closed state shown in FIG. The accompanying effect such as can be obtained.
As a result, the total cost can be reduced.

<Embodiment 2>
FIG. 5 shows a second embodiment of the present invention.
The center seal 40 according to the first embodiment has a structure that easily deforms forward and backward toward the other side. However, if the center seal 40 is excessively deformed, the following problems may occur. For example, when both the heat insulating doors 15 are opened from the closed state shown in FIG. 4, the center seal 40 (seal main body 41) is elastically greatly deformed until the moment when the second magnets 49 are separated from each other. When returning to the original shape by the restoring elasticity, there is a possibility that a large vibration or sound may be generated, and the large deformation is repeated, which is not good in terms of durability.

In the second embodiment, as a measure against the above, the structure of the portion where the center seal 40X is attached to the holding member 60X is changed, and as a result, the internal structure of the center seal 40X is changed. In the following, differences from the first embodiment will be mainly described.
In the seal main body 41X of the center seal 40X, the hard resin leg portion 55 provided on the end surface side of the fourth surface 46 close to the third surface 45 has a thick outer shape in the back surface of the second magnet chamber 48. Is formed so as to project toward the second surface 44 side, and an insertion groove 56 having a cross-sectional saddle shape is formed in the inside thereof in a form opening to the outside of the warehouse.
On the other hand, from the outer surface of the base 61X of the holding member 60X, an attachment portion 67X that fits tightly and slidably is inserted into an insertion groove 56 formed in the leg portion 55 of the center seal 40X. Yes.
As described above, the leg portion 55 whose rigidity is substantially increased by inserting the attachment portion 67X corresponds to the “deformation restricting portion” of the present invention. As a result, in the hollow of the center seal 40X, the leg portion 55 is provided. The (deformation restricting portion) has a structure that enters the second surface 44 between the second magnet chamber 48 and the third surface 45 from the outer surface of the base 61X of the holding member 60X.

  According to the present embodiment, when the center seal 40X is elastically deformed toward the other side, when the third surface 45 is tilted toward the other side, the tilt is restricted by hitting the leg portion 55 (deformation restricting portion). Thus, the deformation amount of the center seal 40X is limited. Therefore, the vibration and sound when the center seal 40X is restored to its original shape when the door is opened can be kept small, so that the operability is excellent and the durability of the center seal 40X is improved. can do. Further, the leg portion 55 (deformation restricting portion) can limit the amount of return deformation even when the second magnet chamber 48 moves backward, and can further improve durability.

<Embodiment 3>
Next, Embodiment 3 of the present invention will be described with reference to FIGS. Also in the third embodiment, the center seal 40Y and the mounting structure for the holding member 60Y are improved. Hereinafter, differences from the first and second embodiments will be mainly described, and portions and members having the same functions as those of the first or second embodiment will be denoted by the same reference numerals, and redundant description will be omitted or simplified.

The center seal 40Y has a seal body 41Y having a first surface 43, a second surface 44Y, and a third surface 45Y and having a portal-shaped cross section that is open to the outside of the warehouse (the lower side in FIG. 6). Here, in particular, the second surface 44Y (corresponding to the base end side of the second surface in the present invention) is formed as thick as about three times the first surface 43. The third surface 45Y is also about twice as thick as the first surface 43, and the end on the outside of the warehouse is bent toward the first surface 43, and the bent end has a cross-sectional surface similar to the second embodiment. A first leg portion 55Y made of hard resin is formed so as to protrude in a form in which the insertion groove 56 forming the mold is opened to the outside of the warehouse.
Here, when the second surface 44Y is made thick, it can be formed in a stable shape by providing a part with high rigidity in forming the seal body 41Y that is scheduled to be deformed. . In addition, since the third surface 45Y is continuously thick with the second surface 44Y, the third surface 45Y is more effective in forming a stable shape and obtaining a restoring force.

The second magnet chamber 48 is formed on the back surface side of the first surface 43, the second magnet 49 is inserted, and the fin portion 50 extends from the end of the second surface 44Y intersecting the third surface 45Y. The same is true in that the extended end of the fin portion 50 is formed so as to be in close contact with the inner surface of the first magnet chamber 32.
On the other hand, a leg piece 58 having a predetermined width is formed from the end of the first surface 43 on the outer side of the warehouse so as to protrude toward the outer side of the warehouse. The outer end of the leg piece 58 is bent inward, and a second leg 59 having a rectangular cross section made of hard resin is formed at the bent end. As a means for increasing the rigidity of the second leg portion 59, the thickness may be increased while the soft resin remains.

  The holding member 60Y includes a base 61Y fixed to the opposing side surface 15A with a screw 62 and a slide lid 65Y that is attached to the surface side of the base 61Y with a space therebetween, and similarly, a heater 69 is provided therein. It is assembled in a flat cylindrical shape that is long in the inside / outside direction as a whole in the inserted form. From the outer surface of the base 61Y of the holding member 60Y, an attachment portion 67Y that fits tightly and slidably is inserted into an insertion groove 56 formed in the first leg portion 55Y of the center seal 40Y. Yes. A mounting cylinder portion 80 having a rectangular cross section is formed so as to protrude substantially at the center width position on the back surface of the slide lid 65Y. In the mounting cylinder portion 80, a second leg portion 59 provided on the center seal 40Y is provided. It is slidably inserted through the cutting groove 81.

  Note that a lip portion 85 for blocking cold air similarly projects from the end of the second surface 44Y of the seal body 41Y intersecting the third surface 45Y. The lip 85 protrudes toward the inside of the cabinet, and then the tip 86 is bent at an acute angle (for example, 75 °) toward the other side. As shown in FIG. 7, the tip portions 86 can be overlapped with each other.

  In the present embodiment, when the left and right heat insulation doors 15 are closed, the second magnet chambers 48 of the left and right center seals 40Y are sealed between the swing end sides of the both heat insulation doors 15 as shown in FIG. The third surface 45Y of the main body 41Y and the leg piece 58 provided with the second leg portion 59 at the tip are tilted and deformed toward the other side, and are brought into close contact with each other and sealed. Further, the front end portions 86 of the lip portions 85 protrudingly formed on both the center seals 40Y overlap each other, and the inside of the portion where the second magnet chambers 48 are in close contact with each other is covered with the both lip portions 85.

Basically, in this embodiment, the seal main body 41Y of each center seal 40Y is easy to advance and retreat toward the other side so as to swing while maintaining the posture in which the first surfaces 43 are parallel to each other. It has become. Therefore, as in the first embodiment, when the magnetic force of the second magnet 49 is used as a reference, the allowable range of the distance between the center seals 40Y for normal adsorption increases, specifically, the center seal 40Y itself It is possible to widen the allowable range of dimensional error and assembly error, and it is possible to cope with secular change (deformation) accompanying use over a long period of time.
On the other hand, by providing two hooking portions of the first leg portion 55Y and the second leg portion 59, the deformation of the center seal 40Y (seal main body 41Y) in the interior direction is further restricted. When the door is opened, the vibration and sound when the center seal 40Y is restored to the original shape can be kept smaller.

Further, since the second surface 44Y of the seal body 41Y is made thick, a large restoring elasticity can be obtained, and when the heat insulating door 15 is opened, the center seal 40Y can be surely retracted to the original position. It becomes. For this reason, for example, when the heat insulating door 15 that has been partially opened is closed, the amount of interference between the center seal 40Y and the heat insulating door 15 of the other party is small, and the heat insulating door 15 is automatically biased to the closed position. Moving, that is, autism can be improved.
Also in the third embodiment, in the hollow of the center seal 40Y, the first leg 55Y (corresponding to the “deformation restricting portion” of the present invention) is the first from the outer surface of the base 61Y of the holding member 60Y. The structure is such that it enters between the second magnet chamber 48 and the third surface 45Y toward the second surface 44Y.
Therefore, when the center seal 40Y is elastically deformed toward the other side, when the third surface 45Y is tilted toward the other side, the tilt is restricted by hitting the first leg 55Y (deformation restricting portion), and the center The deformation amount of the seal 40Y can be limited, and the leg portion 55Y (deformation restricting portion) can limit the backward deformation amount even when the second magnet chamber 48 moves backward.

In addition, the center seal 40Y of the third embodiment has a gap s between the first leg portion 55Y serving as a deformation restricting portion and the second magnet chamber 48, as shown by the chain line in FIGS. Is small (about 0.5 mm), it may be difficult to extrude the center seal 40Y in the shape at the time of mounting.
Therefore, the center seal 40Y may be formed in an open shape as shown by the solid line in FIG. 8, and the first surface 43 may be elastically deformed and closed when attached. In the molded shape, a sufficient space S can be secured between the first leg portion 55Y and the second magnet chamber 48, and therefore, proper extrusion can be performed.

<Embodiment 4>
A fourth embodiment will be described with reference to FIGS. 9 and 10. The fourth embodiment is a further improvement on the third embodiment, and the arrangement structure of the “deformation restricting portion” has been changed so that the center seal 40Z can be properly extruded. It has been added. Hereinafter, differences from the third embodiment will be mainly described, and members and parts having the same functions as those of the third embodiment will be denoted by the same reference numerals, and description thereof will be omitted or simplified.

In the present embodiment, contrary to the third embodiment, the deformation restricting portion 90 is provided on the base 61Z side of the holding member 60Z, and the deformation restricting portion 90 is provided with the third surface 45Z in the seal body 41Z of the center seal 40Z. The protruding end is connected.
Specifically, a deformation regulating portion 90 having a thick rib shape is formed to protrude on the inner surface of the base 61Z of the holding member 60Z, and the deformation regulating portion 90 is provided when the center seal 40Z is attached. The second magnet chamber 48 can enter along a region outside the warehouse on the back surface. Inside the deformation restricting portion 90, an insertion groove 91 having a T-shaped cross section is formed over the entire length in a form opening on the surface opposite to the side facing the second magnet chamber 48 in the deformation restricting portion 90. Has been.
On the other hand, the protruding end of the third surface 45Z of the center seal 40Z is bent at a right angle toward the first surface side 40Z, and the bent end has a belt shape inserted almost tightly into the widened portion 92 of the insertion groove 91 described above. A hook leg portion 55Z is formed. The latch leg 55Z is made of hard resin.

  In this embodiment, in the molded shape of the center seal 40Z, as shown in FIG. 9, a sufficient distance Z (for example, about 3 mm) can be ensured between the retaining leg 55Z and the second magnet chamber 48. Can be extruded. Further, since the center seal 40Z can be mounted on the holding member 60Z without being elastically deformed in a molded shape, a stable mounting shape can be secured without causing unnecessary return deformation or the like.

<Embodiment 5>
11 and 12 show the fifth embodiment. In said Embodiment 4, when one heat insulation door 15 is opened from the closed state shown by FIG. 10, the other heat insulation door 15 may open unexpectedly. This phenomenon occurs when “friction force between both center seals 40Z> force required to open one heat insulating door 15”. To avoid this, the friction force between both center seals 40Z can be reduced. Good.
Here, “the frictional force between the center seals 40Z = the magnetic force of the second magnet 49 × the friction coefficient of the contact surface (first surface 43) of the center seal 40Z”. It is conceivable to reduce the magnetic force, but in that case, the space between the heat insulating doors 15 that can be sealed becomes narrow, and it is necessary to tighten the dimensional tolerance of each member in order to realize this, leading to high costs. Not good.

  Therefore, in the fifth embodiment, means for reducing the “friction coefficient of the contact surface (first surface 43) of the center seal 40Z”, which is another parameter related to the frictional force between the center seals 40Z, is employed. Specifically, as shown in FIGS. 11 and 12, the surface layer 95 of the first surface 43 (including the leg pieces 58) of the center seal 40Z is formed of a material having a smaller friction coefficient than that of the base 96. Yes.

More specifically, the base 96 of the center seal 40Z is made of a material having high flexibility but a high coefficient of friction. For example, (1) olefin elastomer (PP (polypropylene) and EPDM (rubber) ), (2) soft vinyl chloride, (3) soft rubber, and the like. In addition, since the latching leg part 55Z is calculated | required that rigidity is high, it is formed with hard resin.
On the other hand, the surface layer 95 of the first surface 43 (including the leg pieces 58) is formed of a material that is poor in flexibility but has a low coefficient of friction. For example, (1) olefinic elastomer and PE (polyethylene) ), (2) PE (polyethylene), (3) Teflon (registered trademark), and the like.
With the above structure, the frictional force between the center seals 40Z when the door is closed can be lowered, and even when one heat insulating door 15 is opened with a relatively small operating force, the other heat insulating door 15 is brought along. The situation of opening can be avoided.

<Embodiment 6>
A sixth embodiment will be described with reference to FIGS. The sixth embodiment is obtained by further improving the fourth embodiment. More specifically, the fitting leg portion 59U at the bent end of the leg piece 58 that projects from the end of the first surface 43 of the center seal 40U on the outside of the warehouse is attached to the mounting cylinder portion 80U ( The structure inserted into the mounting groove of the present invention is changed. Similarly, differences from the fourth embodiment will be mainly described below, and members and parts having the same functions as those of the fourth embodiment will be denoted by the same reference numerals, and description thereof will be omitted or simplified.

  As shown in FIG. 13, the fitting leg portion 59U formed at the bent end of the leg piece 58 of the first surface 43 is formed in a band shape like the second leg portion 59 of the fourth embodiment. The two legs 59 are formed as thin as about 2/3 of the thickness. On the other hand, the cutting groove 81U formed on the outer surface of the mounting cylinder part 80U is formed wider than the cutting groove 81 of the mounting cylinder part 80 of the fourth embodiment. Roundness R is attached to the corner of the groove surface inside the cut groove 81U.

Next, a procedure for mounting the center seal 40U will be described. First, the center seal 40U is slidably mounted on the holding member 60U while only the latching leg portion 55Z is fitted in the insertion groove 91 of the deformation restricting portion 90 of the base 61U and is slid along it. After that, as shown in FIG. 14, the second magnet 49 is inserted into the second magnet chamber 48, and the heater cover 100 is covered and fixed on the upper and lower surfaces of the holding member 60 </ b> U.
Next, as shown in FIG. 15, the fitting leg portion 59 </ b> U formed at the bent end of the leg piece 58 is elastically bent in an oblique posture, and is attached to the mounting cylinder portion through the wide cut groove 81 </ b> U. When inserted in the width direction in 80U and further pushed in, as shown in FIG. 16, the fitting leg portion 59U is elastically restored to its original posture and fitted into the mounting tube portion 80U. As a result, the fitting leg portion 59U It will be in the state inserted through the full length of the attachment cylinder part 80U.

When the center seal is attached to the holding member, as shown in FIG. 10, both the retaining leg 55Z and the leg 59 at the bent end of the leg piece 58 are inserted into the insertion groove 91 and the mounting cylinder 80, respectively. Appropriate skill is required when sliding and fitting while sliding.
On the other hand, in the present embodiment, as described with reference to FIGS. 14 to 16, only the retaining leg portion 55Z is first slid into the insertion groove 91 while being slid, and the other fitting leg portion 59U is The fitting tube portion 80U is inserted by fitting in the width direction. For this reason, the center seal 40U can be mounted without any skill.

As another installation procedure of the center seal 40U, after fitting the retaining leg portion 55Z into the insertion groove 91 and sliding it for a predetermined dimension, the fitting leg portion 59U is fitted in the mounting cylinder portion 80U in the width direction, After that, the center seal 40U may be slid on the entire length. As in the fourth embodiment, it can be said that the work is easier than the case where the latching leg portion 55Z and the second leg portion 59 are fitted into the insertion groove 91 and the mounting cylinder portion 80 and mounted by sliding.
When the fitting leg portion 59U at the bent end of the leg piece 58 is fitted in the width direction with respect to the mounting cylinder portion 80U as in the sixth embodiment, a large force is applied to the leg piece 58 toward the inner side. When the center seal 40U is attached to the holding member 60U, the fitting leg 59U may be pulled out through the slit groove 81U while being elastically deformed. It is confirmed that there is no problem in practical use because there is little possibility that a large pulling force is applied to the plate.

<Embodiment 7>
A seventh embodiment will be described with reference to FIGS. In the seventh embodiment, the structure of the mounting portion of the center seal 40Y is changed with respect to the third embodiment.
The structure of the edge side of the heat insulating door 15 where the center seal 40Y is mounted will be described again with reference to FIGS. 6 and 17. The center seal 40Y slides relative to the holding member 60Y composed of the base 61Y and the slide lid 65Y. At the same time, the heater cover 100 is attached, and finally a cap 70 (see FIG. 20) serving as a stopper is placed so as to contact the upper and lower end surfaces of the holding member 60Y.
Here, since the center seal 40Y is deformed and moved in the left-right direction as the heat insulating door 15 is opened and closed, the length of the center seal 40Y needs to be shorter than the interval between the upper and lower caps 70. On the other hand, since the center seal 40Y is slidably mounted in the vertical direction with respect to the holding member 60Y as described above, even if the holding member 60Y and the upper end surfaces are mounted with the upper end surfaces aligned at the beginning, the heat insulating door 15 As the opening / closing operation is repeated, the center seal 40Y gradually lowers, and there is a problem that a gap is formed between the cap 70 and the upper end of the center seal 40Y.

The seventh embodiment has been completed as an improvement measure, and as shown in FIGS. 17 and 18, the upper end portion of the base 61Y of the holding member 60Y is cut by a predetermined size. When the center seal 40Y is attached to such a holding member 60Y with the slide lid 65Y and the upper end surfaces aligned, the insertion groove 56 of the first leg 55Y is empty because the mounting portion 67Y is cut off. Therefore, as shown in FIG. 18, the coking material C is filled in the space 102 and solidified. Thereby, as shown in FIG. 19B, the lower surface C1 of the caulking material C is fixed to the upper surface of the mounting portion 67Y by adhesion, and is fixed to the mounting portion 67Y as shown in FIG. The inner surface of the insertion groove 56 of the first leg portion 55Y is fixed to the peripheral surface C2 of the caulking material C thus formed by adhesion. As a result, the center seal 40Y is suspended and fixed via the caulking material C in a form in which the upper edge is aligned with the slide lid 65Y.
Therefore, a situation where the center seal 40Y is lowered downward is avoided, and a gap is prevented from being formed between the center seal 40Y and the cap 70 as shown in FIG.
When exchanging the center seal 40Y, the center seal 40Y is pulled upward after removing the cap 70. At this time, the caulking material C is pulled off from the upper surface of the mounting portion 67Y having a relatively small area. Therefore, the center seal 40Y can be easily pulled out, and the center seal 40Y can be replaced in a short time.

<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) You may omit this about the vertical packing provided in the rocking | fluctuation end side of the heat insulation door. In this case, the extended end portion (fin portion 50) of the second surface of the seal body of the center seal overlaps with the side edge portion on the swing end side of the back surface of the heat insulating door. Here, the side edge portion on the rocking end side on the back surface needs to be disposed flush with the surface of the first magnet chamber of the upper and lower packings, and the extended end portion (fin portion 50) of the second surface. It is necessary to make it overlap with the height region exposed in the cabinet except for the portion protruding from the top and bottom of the lip portion 52 (the portion that is in close contact with the mouth edge portion of the front opening 13) of the same side edge portion. is there.
(2) In the third embodiment, the fixing means on the protruding end side of the third surface in the seal body of the center seal is the same as in the first embodiment, and the leg portions made of hard resin protruding toward the outer side of the warehouse are It is good also as a structure inserted in the attachment groove | channel formed in the wall surface inside the store | warehouse | chamber in the base of a holding member.
(3) The leg provided on the center seal basically only needs to be rigid enough to prevent it from coming off the mating part when an external force is applied. It may be formed of a soft resin.

(4) The configuration in which the surface layer of the first surface of the center seal exemplified in the fifth embodiment is formed of a material having a low coefficient of friction can be similarly applied to the center seals according to other embodiments.
(5) In addition to the center seal of the fifth embodiment, the second leg provided at the bent end of the leg piece in the center seal illustrated in the third and fourth embodiments may be formed of a material having a low friction coefficient. Good. The operation of inserting the second leg portion into the mounting tube portion is facilitated.
(6) In the mounting procedure of the center seal in the sixth embodiment, a second magnet may be inserted into the center seal in advance, and the center seal may be mounted on the holding member covered with the heater cover.
(7) Similarly, in the sixth embodiment, the operation of inserting the second magnet into the second magnet chamber may be performed after the center seal is attached to the holding member.
(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, etc. 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 15 ... Heat insulation door 15A ... Opposite side surface 30 ... Packing 32 ... 1st magnet chamber 40, 40U, 40X, 40Y, 40Z ... Center seal 41, 41X, 41Y, 41Z ... Seal body 43 ... first surface 44,44Y ... second surface 45,45Y, 45Z ... third surface 46 ... fourth surface 47 ... leg portion 48 ... second magnet chamber 49 ... second magnet (magnet) 50 ... fin portion (Extended end portion of the second surface) 55 ... Leg portion (deformation restricting portion) 55Y ... First leg portion (deformation restricting portion) 55Z ... Hook leg portion 58 ... Leg piece 59 ... Second leg portion 59U ... Fitting leg Part 60, 60U, 60X, 60Y, 60Z ... Holding member 61, 61U, 61X, 61Y, 61Z ... Base 65, 65U, 65Y ... Slide lid 67 ... Mounting groove 67X, 67Y ... Take Attached part 80: mounting cylinder part 80U: mounting cylinder part (mounting groove) 81U ... slit groove 90 ... deformation restricting part 91 ... insertion groove 92 ... widening part 95 ... surface layer 96 ... base

Claims (7)

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 as to be able to open and close in a double swing manner, and a magnet is attached to a side edge of each heat insulating door facing the other side. In what is provided with a center seal made of elastic material with
The center seal extends to the heat insulating door side at a right angle from a first surface facing the mating side in parallel with each other and from the inner side end portion of the first surface. A second surface that overlaps the back surface of the heat insulating door, and a third surface that protrudes from the front side of the extended end of the second surface toward the outside of the warehouse, and the protruding end is fixed to the side edge of the heat insulating door; Comprising a space surrounded by the first surface, the second surface, and the third surface ,
The magnet is built in the inner corner of the back surface of the first surface,
The pair of left and right center seals are configured such that, when both magnets face each other and attract each other, the second surface advances toward the other side and the third surface tilts toward the other side. A door device for a cooling storage, which is configured to be elastically deformable . In the space surrounded by the first surface, the second surface, and the third surface of the center seal, the deformation restricting portion enters the space from the side edge of the heat insulating door toward the interior direction. The door device of the cooling storage according to claim 1, wherein The deformation restricting portion is formed in a form protruding from the side edge of the heat insulating door along the back surface of the magnet,
On the surface opposite to the side facing the magnet in the deformation restricting portion, an insertion groove whose inside is widened is formed along the length direction,
Wherein the projecting end of said third surface of the center seal, the door device of the cooling storage according to claim 2, wherein a Kaketomeashi portion to be inserted into expansion width portion of the insertion groove is formed.   The end on the outside of the first surface of the center seal is extended to the outside of the center seal, and the extended end is fixed to the side edge of the heat insulating door. The door device of the cooling storehouse as described in any one of 3. On the surface facing the side edge of the other heat insulating door at the side edge of the heat insulating door, an attachment groove that is open on the same surface and has an inward width is formed along the length direction,
Wherein the first surface of the extended end, the door system of cooling storage according to claim 4, wherein the fittable Hamagoashi portion is formed through the opening in the expansion width of the mounting groove.   6. The cooling storage door device according to claim 1, wherein a surface layer of the first surface of the center seal is formed of a material having a low coefficient of friction.   The cooling storage according to any one of claims 1 to 6, wherein a base end portion side of the second surface of the center seal is formed to be thicker than an extension end portion. Door device.

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