JP6815948B2 - refrigerator - Google Patents

Description

The present invention relates to a refrigerator.

Patent Document 1 describes a refrigerator provided with an operation panel on the side surface of the refrigerator. In the refrigerator described in Patent Document 1, a cover is provided in order to prevent the foamed heat insulating material from invading the substrate of the operation panel.

JP-A-2003-176978

However, the invention described in Patent Document 1 has a structure in which water condensed on the back surface of the substrate and water that has entered from the outside of the cover through a slight gap accumulates inside the cover. Therefore, if water accumulates to some extent, the surface of the substrate may be submerged in water.

The present invention solves the above-mentioned problems, and an object of the present invention is to provide a highly reliable refrigerator.

In order to solve the above problems, in the present invention, a unit member having a front surface member, a circuit board provided on the back surface side of the front surface member, and a substrate storage portion for accommodating the circuit board and fixing the surface member. A heat insulating box body is provided between the inner box and the outer box, and the unit member is arranged on at least one of the left and right side surfaces of the inner box. The back surface of the front surface member has a heat insulating box. A drainage groove is formed at the lower end in the vertical direction, the rib is provided on the upper side of the circuit board, and the upper surface of the rib has an inclined surface that descends from the back surface side to the front surface side of the front surface member. It is characterized by. Other solutions will be described later.

According to the present invention, a highly reliable refrigerator can be provided.

It is external perspective view of the refrigerator which concerns on 1st Embodiment. It is a front view which shows the inside of a refrigerating room. FIG. 2 is a cross-sectional view taken along the line AA of FIG. It is an enlarged view of the main part of FIG. FIG. 2 is a cross-sectional view taken along the line BB of FIG. It is a top view which looked at the state which left the control board from the operation panel and removed the board storage part from the back side. It is a vertical sectional view of an operation panel. It is a schematic diagram which shows the positional relationship between an operation panel and a heat insulating box body, (a) is a 1st Embodiment, (b) is a comparative example. It is the schematic which shows the positional relationship between the operation panel of 2nd Embodiment, and a heat insulating box body. It is the schematic which shows the positional relationship between the operation panel of 3rd Embodiment and a heat insulating box body. (A) is a graph showing the relationship between urethane density and foaming pressure, and (b) is a schematic diagram showing the load and the amount of deformation when determining the case rigidity. It is the schematic which shows the state which provided the intervening member between the substrate accommodating part and the vacuum heat insulating material.

Hereinafter, the refrigerators 1A, 1B, and 1C according to the embodiment of the present invention will be described with reference to the drawings. In the following description, the "up / down", "left / right", and "front / back" directions shown in FIG. 1 will be used as a reference. Further, in the following description, a 6-door refrigerator will be described as an example, but the present invention is not limited to the 6-door refrigerator. Further, in each embodiment, the same configuration is designated by the same reference numerals and duplicated description will be omitted.

(First Embodiment)
FIG. 1 is an external perspective view of the refrigerator according to the first embodiment.

As shown in FIG. 1, the refrigerator 1A is configured by, for example, arranging a refrigerator chamber 2, an ice making chamber 3, an upper freezer compartment 4, a lower freezer compartment 5, and a vegetable compartment 6 from above. The ice making chamber 3 and the upper freezing chamber 4 are provided side by side. The refrigerating room 2 is provided with double doors 2a and 2b that are divided into left and right.

Further, in the refrigerator 1A, the outside and the inside of the refrigerator are separated by a heat insulating box body 10 formed by filling the inside with a foam heat insulating material. The heat insulating box 10 includes a vacuum heat insulating material 50 (FIG. 3) in addition to the foam heat insulating material, and the vacuum heat insulating material 50 enhances the heat insulating property. The heat insulating box body 10 includes an outer box 11 forming an outer shell, and an inner box 12 constituting each storage room for storing foods in the refrigerating room 2, the ice making room 3, the upper freezing room 4, the lower freezing room 5, and the vegetable room 6. And have.

Refrigerator 1A also includes a known refrigeration cycle that includes a compressor (compressor), a condenser (condenser, not shown), a capillary tube (decompression means, not shown) and a cooler (evaporator).

Further, the refrigerator 1A is provided with an operation panel 20 (unit member) in the refrigerator compartment 2. The operation panel 20 is provided on the left side surface of the refrigerator. The position of the operation panel 20 is not limited to the left side surface, and may be provided on the right side surface.

Further, the operation panel 20 has a surface member 21 having a rectangular shape, and the surface member 21 is provided with a plurality of (six in this embodiment) pressing type operation buttons 22. Further, the operation panel 20 is located on the front side of the partition shelf 2c provided in the refrigerator compartment 2.

FIG. 2 is a front view showing the inside of the refrigerator compartment. Note that FIG. 2 shows a state in which the doors 2a and 2b and the internal partition shelf 2c and the like are removed.

As shown in FIG. 2, the outer box 11 of the heat insulating box body 10 is made of a thin steel plate, and constitutes the housing of the refrigerator main body (heat insulating box body 10). Further, the outer box 11 is formed by integrally molding the left and right side surface plates 11a and 11b and the top plate 11c from a steel strip using a forming roll or the like, and the bottom plate (not shown) and the back plate 11d (FIG. 3) can be assembled by screwing or the like.

The inner box 12 of the heat insulating box body 10 is formed by a vacuum forming method in which one resin sheet is heated, stretched by applying an air blow, placed in a mold, and molded into a container shape. Further, the inner box 12 is formed by integrally molding the left side wall 12a, the right side wall 12b, the back wall 12c, the top wall 12d (see FIG. 1), and the bottom wall 12e (see FIG. 1).

FIG. 3 is a cross-sectional view taken along the line AA of FIG.

As shown in FIG. 3, the heat insulating box 10 is formed in a U shape in a horizontal cross-sectional view. The side plates 11a and 11b of the outer box 11 extend in parallel in the front-rear direction.

The side wall 12a of the inner box 12 has an inclined surface 12a1 that is gently inclined so as to approach the side plate 11a (outer surface) of the outer box 11 from the back side (rear side) to the front side (front side). There is. The inclined surface 12a1 is for ensuring releasability from the mold, and is a so-called punching taper. The operation panel 20 is provided on the surface (side wall 12a) on which the inclined surface 12a1 (punch taper) is formed. The side wall 12b is also provided with an inclined surface symmetrically with the side wall 12a.

Further, a vacuum heat insulating material 50 is provided inside the heat insulating box 10 (inside the wall). The vacuum heat insulating material 50 is attached to the inner surface of the side plate 11a (outer plate) of the outer box 11. Further, the front end of the vacuum heat insulating material 50 is located on the front side (front side, front side) of the operation panel 20, and the rear end is arranged so as to extend to the substantially rear end of the side plate 11a.

Further, the vacuum heat insulating material 50 contains a glass wool layer, which is an aggregate of inorganic fibers forming a core material, an adsorbent, etc., which is arranged in the central portion, in an inner bag material (not shown) to provide gas barrier properties such as aluminum foil. It is vacuum packaged with the outer cover material.

As the inner bag material (not shown), a polyethylene film, a polypropylene film, a polyethylene terephthalate film, a polybutylene terephthalate film, or the like is used. That is, as the inner bag material, a material having low hygroscopicity, heat welding is possible, and outgas (gas leakage) is small is used.

As the adsorbent, a physical adsorption type synthetic zeolite that captures water and gas molecules in the pores is used. The adsorbent does not have to be synthetic zeolite, as long as it adsorbs water and gas, and a chemical reaction type adsorbent that adsorbs water and gas by a chemical reaction such as silica gel, calcium oxide, calcium chloride, and strontium oxide is used. It can also be used.

As for the outer cover material, a polypropylene film having low hygroscopicity is provided as a surface layer, and an aluminum vapor deposition layer is provided on a polyethylene terephthalate film as a moisture-proof layer. The gas barrier layer is formed by providing an aluminum-deposited layer on an ethylene vinyl alcohol copolymer film and laminating the gas barrier layer so as to face the aluminum-deposited layer of the moisture-proof layer.

In the present embodiment, the panel-shaped (flat plate-shaped) vacuum heat insulating material 50 is attached to the inner wall surface of the side plate 11a (outer plate), and between the side plate 11a (outer plate) and the side wall 12a (inner plate). The space formed in is filled with a foam heat insulating material such as rigid urethane foam.

FIG. 4 is an enlarged view of a main part of FIG.

As shown in FIG. 4, the operation panel 20 includes a surface member 21 provided with an operation button 22 (see FIG. 1), a control board 31 (circuit board) provided on the back surface side of the front surface member 21, and a control board 31. It is configured to include a substrate storage portion 41 for storing and fixing the surface member 21. The operation button 22 (see FIG. 1) is, for example, a pressing operation type, and can be used to control the temperature inside the refrigerator compartment 2, the ice making chamber 3, the upper freezer compartment 4, the lower freezer compartment 5, the vegetable compartment 6, and the like. It is operated when changing.

The surface member 21 has a panel portion 21a provided with an operation button 22 (see FIG. 1) and a rib 21b extending from the outer peripheral edge portion of the back surface of the panel portion 21a toward the side plate 11a of the outer box. There is. Further, the surface member 21 is fixed to the substrate storage portion 41 by inserting the rib 21b into the rectangular mounting hole 12f formed through the side wall 12a (inclined surface 12a1). Further, the panel portion 21a has a rectangular shape larger than the opening area of the mounting hole 12f, and the entire outer peripheral edge portion 21r of the panel portion 21a is configured to come into contact with the entire opening edge portion 12g of the mounting hole 12f. There is. As a result, the entire mounting hole 12f is closed by the surface member 21, and the mounting hole 12f cannot be seen from the outside (inside the refrigerator).

Further, in consideration of the punching taper, the front side (front side) of the surface member 21 protrudes from the surface of the side wall 12a toward the inside of the refrigerator (toward the center in the width direction of the inside) rather than the back side (rear side). It is configured to do (protruding). Further, the surface 21a1 of the surface member 21 (panel portion 21a) is configured to be substantially parallel (or parallel) to the vacuum heat insulating material 50. In addition, substantially parallel means a direction including parallel and closer to parallel than the inclination formed by the surface 21a1 and the inclined surface 12a1.

The control board 31 is composed of a square plate-shaped circuit board (appropriately abbreviated as “board”) on which various electric parts and electronic parts are mounted, and is located inside the rib 21b of the surface member 21. In other words, the control board 31 is configured to be surrounded by the ribs 21b. As the number of operation menus on the operation panel 20 increases (multi-functions), the size of the board increases. The signal from the control board 31 is sent to the main board provided on the ceiling of the heat insulating box 10, and the temperature inside the refrigerator is controlled from the main board.

The board storage portion 41 is arranged on the back side of the side wall 12a (inside the heat insulating box body 10), and extends along the back surface of the side wall 12a from the recess 42 that houses the control board 31 and the opening edge of the recess 42. It is configured to have a brim portion 43.

The recess 42 has a bottom surface portion 42a arranged in parallel with the control board 31 and a side surface portion 42b extending upright from the peripheral edge portion of the bottom surface portion 42a toward the side wall 12a, and is directed toward the mounting hole 12f. It is configured to open. Further, the recess 42 is configured so that the depth H1 from the opening on the front side (front side) is shallower than the depth H2 from the opening on the back side (rear side) (H2> H1).

Further, the bottom surface portion 42a of the recess 42 is configured so that the back surface 42c on the outer box 11 side is substantially parallel (or parallel) to the vacuum heat insulating material 50. As a result, the gap S between the back surface 42c of the bottom surface portion 42a and the vacuum heat insulating material 50 becomes uniform from the back surface side to the front surface side. In addition, substantially parallel means a direction that includes parallelism and is closer to parallel than the inclination formed by the back surface 42c and the inclined surface 12a1.

Further, the bottom surface portion 42a of the recess 42 is configured so that the back surface 42c on the outer box 11 side is substantially parallel (or parallel) to the outer box 11 (side plate 11a). As a result, when the vacuum heat insulating material 50 is attached to the back surface of the side plate 11a, the gap S between the back surface 42c of the bottom surface portion 42a and the vacuum heat insulating material 50 can be made uniform from the back surface side to the front surface side.

FIG. 5 is a cross-sectional view taken along the line BB of FIG.

As shown in FIG. 5, the rib 21b of the surface member 21 is formed with a contact portion 21d with which the outer peripheral edge portion of the control substrate 31 abuts. As a result, the height position of the front surface member 21 from the back surface can always be constant.

The recess 42 of the substrate storage portion 41 is formed with a reinforcing portion 41s that protrudes from the bottom surface portion 42a toward the surface member 21. The reinforcing portion 41s is formed in a cylindrical shape and is formed so as to project from the center of the bottom surface portion 42a. Further, the tip 41s1 of the reinforcing portion 41s protrudes to a position where it is flush with the side wall 12a.

If the items to be stored in the board storage section 41 are small, the board storage section 41 can be made small, and even if the back surface of the board storage section 41 is filled with urethane (foamed heat insulating material), the board storage section 41 The foaming pressure applied to is also small. However, as the number of operation menus increases and the size of the substrate increases, the substrate may be deformed due to the foaming pressure of urethane. Therefore, when filling urethane, it is necessary to apply a jig for preventing deformation of the substrate storage portion from the surface side of the side wall. By providing the reinforcing portion 41s in the substrate accommodating portion 41 in this way, deformation due to foaming pressure can be suppressed. The tip 41s1 of the reinforcing portion 41s may extend to a position where it abuts on the jig.

Further, since the reinforcing portion 41s is formed in the substrate accommodating portion 41, a through hole 31a through which the reinforcing portion 41s can be inserted is formed in the center of the control substrate 31. As a result, even if the reinforcing portion 41s is projected from the bottom surface portion 42a to the surface flush with the side wall 12a, the control board 31 can be stored in the board storage portion 41.

FIG. 6 is a plan view of a state in which the board storage portion is removed while leaving the control board from the operation panel, as viewed from the back side.

As shown in FIG. 6, the control board 31 has a rectangular shape in a plan view and is arranged inside the rib 21b formed on the back surface of the front surface member 21. The outer peripheral edge of the control board 31 is located in the vicinity of the rib 21b.

Further, in the control board 31, the edge portion of the control board 31 is locked by the claw portions 21c, 21c, 21d, 21d formed on the back surface of the front surface member 21. As a result, the control board 31 is securely held by the surface member 21.

The claw portions 21c and 21c are formed on the upper portion of the control substrate 31, are integrally formed with the ribs 21b, and are arranged apart from each other in the front-rear direction. Further, the claw portion 21c is formed on the wall surface of the rib 21b on the control substrate 31 side. The claw portions 21d and 21d are formed so as to project from the back surface of the front surface member 21, and are arranged so as to be separated from each other in the front-rear direction.

The ribs 21b are controlled by upper ribs 21e formed along the upper side portions 31b of the control substrate 31 and side ribs 21f and 21g formed along the side side portions 31c and 31c on both front and rear sides of the control substrate 31. It has lower ribs 21h and 21i formed along the lower side portion 31d of the substrate 31, and is formed in a substantially U-shape (substantially C-shape) in a plan view. The lower ribs 21h and 21i are formed short from the lower ends of the side ribs 21f and 21g in the front-rear direction facing each other. Projected portions 21h1,21i1 extending in the thickness direction of the surface member 21 (direction orthogonal to the paper surface of FIG. 6) are formed on the lower surface of the tip of the lower ribs 21h and 21i.

On the back surface of the front surface member 21, drainage grooves 21j, 21j, 21k, 21k extending in the vertical direction are formed at the lower end portion. The drainage grooves 21j and 21j are located on the rear side in the front-rear direction. The drainage grooves 21k and 21k are located on the front side in the front-rear direction. Further, the drainage grooves 21j and 21k are formed by notching the back surface of the front surface member 21 in a gutter shape (substantially semicircular shape). Further, the drainage grooves 21j and 21j are formed at positions that do not overlap with the lower rib 21h in the vertical direction. The drainage grooves 21k and 21k are formed at positions that do not overlap with the lower rib 21i in the vertical direction.

Further, the upper ribs 21e are inclined toward the front (one in the width direction) from the center in the front-rear direction (the center in the width direction in the front view) and the rear (the other in the width direction). It has a ramp 21e2 that inclines so as to descend toward it.

FIG. 7 is a vertical sectional view of the operation panel.

As shown in FIG. 7, the upper rib 21e has an inclined surface portion 21e3 that descends from the back surface side to the front surface side of the surface member 21. As a result, even if water (condensation water) or the like flows into the upper rib 21e from the gap between the operation panel 20 and the side wall 12a, it does not flow to the bottom surface portion 42a side of the substrate storage portion 41, so that the control board 31 Can be protected.

By the way, since the inside of the refrigerator compartment 2 (inside the refrigerator) is in a low temperature environment, if warm air enters the refrigerator compartment 2 by opening and closing the doors 2a and 2b, dew condensation may occur, and the control board 31 is protected from dew condensation (protection). There is a need to. Therefore, by changing the shape of the rib 21e to the shape described with reference to FIGS. 6 and 7, the control substrate 31 can be protected from dew condensation. That is, as shown by the broken line arrow in FIG. 6, when dew condensation occurs in the refrigerator and the dew condensation water invades the back surface side of the front surface member 21 from the upper part of the front surface member 21, the dew condensation water is first received by the upper rib 21e. be able to. At this time, since the upper ribs 21e have ramps 21e1, 21, 21e2, the condensed water flows in the front-rear direction (horizontal direction in the drawing) through the ramps 21e1, 21, 21e2. Further, at this time, since the upper rib 21e has the inclined surface portion 21e3 (see FIG. 7), the condensed water does not flow down to the control board 31 side.

Then, the condensed water that has flowed to the end portion of the upper rib 21e in the front-rear direction flows downward while contacting the outer surfaces of the side ribs 21f and 21g due to surface tension. Then, the condensed water that has flowed to the lower ends of the side ribs 21f and 21g flows inward while contacting the lower surfaces of the lower ribs 21h and 21i by surface tension. Then, the condensed water that has flowed to the tips of the lower ribs 21h and 21i hits the protrusions 21h1, 21i1 formed on the lower surface of the tips of the lower ribs 21h and 21i and flows downward. Then, the dew condensation water that has flowed down flows out of the surface member 21 through the drainage grooves 21j, 21j, 21k, and 21k. By forming the flow path of the dew condensation water in this way, the control board 31 can be protected from dew condensation.

Next, the effects of the invention will be described with reference to the first embodiment and the comparative example. 8A and 8B are schematic views showing the positional relationship between the operation panel and the heat insulating box, where FIG. 8A is a first embodiment and FIG. 8B is a comparative example.

In the comparative example shown in FIG. 8B, the back surface 142c of the substrate storage portion 141 is formed following the inclined surface 12a1, and the surface 121a of the surface member 121 is formed following the inclined surface 12a1. Is. In the comparative example configured in this way, in the gap S100 formed between the back surface 142c of the substrate storage portion 141 and the vacuum heat insulating material 50 (front surface 50s), the gap on the front side is narrower than the gap on the back side. , The fluidity of the foam heat insulating material in the gap on the front side deteriorates. Further, the vacuum heat insulating material 50 is pressed by the substrate housing portion 41, causing problems such as leakage of the vacuum heat insulating material 50.

Therefore, in the first embodiment, as shown in FIG. 8A, the back surface 42c of the substrate accommodating portion 41 and the vacuum heat insulating material 50 are made parallel (substantially parallel). That is, with respect to the protrusion (protrusion amount) from the side wall 12a of the inner box 12 to the back side, the protrusion amount (dimension) a1 on the front side is smaller (smaller) than the protrusion amount (dimension) b1 on the back side. As a result, the gap S between the back surface 42c of the substrate storage portion 41 and the vacuum heat insulating material 50 (front surface 50s) becomes uniform from the back surface side to the front surface side. As a result, the dimensions of the vacuum heat insulating material 50 and the back surface 42c of the substrate storage portion 41 (the back surface of the operation panel 20) can be shortened. Further, the thickness dimension of the vacuum heat insulating material 50 can be increased, and the heat insulating property of the refrigerator 1A can be improved. Further, in the first embodiment, since the gap between the substrate storage portion 41 and the vacuum heat insulating material 50 can be reduced, the wall thickness of the refrigerator 1A can be reduced (the distance between the side plate 11a and the side wall 12a can be shortened). By reducing the wall thickness of the refrigerator 1A, the internal capacity of the refrigerator compartment 2 can be increased.

Further, in the first embodiment, as shown in FIG. 8A, the back surface 42c of the substrate storage portion 41 and the side surface plate 11a (outer box 11) are parallel (substantially parallel). As a result, the same effect as when the back surface 42c of the substrate storage portion 41 and the vacuum heat insulating material 50 are parallel (substantially parallel) can be obtained.

Further, in the comparative example of FIG. 8B, if the back surface 142c of the substrate storage portion 141 is oriented as indicated by the alternate long and short dash line L100 and the back surface 142c and the vacuum heat insulating material 50 are made substantially parallel, the control board 31 is stored. Space cannot be secured.

Therefore, in the first embodiment, as shown in FIG. 8A, the surface member 21 is formed so that the front side projects from the side wall 12a (side surface) to the inside of the refrigerator rather than the back side. That is, with respect to the protrusion from the side wall 12a of the inner box 12 to the front side, the protrusion amount (dimension) a2 on the front side is larger (larger) than the protrusion amount (dimension) b2 on the back side. As a result, a storage space for the control board 31 can be secured, and the back surface 42c of the board storage portion 41 and the vacuum heat insulating material 50 can be configured to be substantially parallel (or substantially parallel). As a result, the dimensions of the vacuum heat insulating material 50 and the back surface 42c of the substrate storage portion 41 (the back surface of the operation panel 20) can be reduced. Further, the thickness dimension of the vacuum heat insulating material 50 can be increased, and the heat insulating property of the refrigerator 1A can be improved. Further, in the first embodiment, since the gap between the substrate storage portion 41 and the vacuum heat insulating material 50 can be reduced, the wall thickness of the refrigerator 1A can be reduced (the distance between the side plate 11a and the side wall 12a can be shortened). By reducing the wall thickness of the refrigerator 1A, the internal capacity of the refrigerator compartment 2 can be increased. The back surface of the substrate storage portion 41 is not provided with ribs extending toward the vacuum heat insulating material 50. As a result, it is possible to prevent the vacuum heat insulating material 50 from leaking due to the ribs coming into contact with the vacuum heat insulating material 50, and to prevent the leak, the distance between the vacuum heat insulating material 50 and the substrate housing 41 is made larger than necessary. No need. This is particularly effective when the operation button 22 is a pressing type instead of a touch type.

Further, in the first embodiment, a recess 21t (see FIG. 6) is formed on the back surface of the surface on the side (front side) where the surface member 21 is projected (engraved to the edge). As a result, by forming the recess 21t, the back edge portion of the front surface member 21 is formed in a brim shape, so that the strength of the surface member 21 can be improved. In addition, the space inside the operation panel 20 can be effectively used.

Further, in the first embodiment, ribs (upper ribs 21e and side ribs 21f, 21g) extending downward from the upper side portion 31b of the control board 31 through the side side portions 31c project from the back surface of the front surface member 21. The upper surface of the upper rib 21e is formed and has an inclined surface portion 21e3 that descends from the back surface side to the front surface side of the surface member 21 (see FIG. 7). As a result, it is possible to prevent the condensed water from flowing into the control board 31, protect the control board 31, and improve the reliability of the operation panel 20.

Further, in the first embodiment, the upper surface of the upper rib 21e has ramps 21e1, 21e2 that are inclined so as to descend from the center in the width direction toward both sides in the front view. As a result, the water (droplets) that has entered from above the operation panel 20 can be guided to the side ribs 21f and 21g without accumulating on the upper ribs 21e, and the control board 31 can be protected.

Further, in the first embodiment, drainage grooves 21j and 21k are formed at the lower ends in the vertical direction on the back surface of the front surface member 21. As a result, even if water should enter the substrate storage portion 41, it can be drained from the drainage grooves 21j and 21k, and the reliability of the operation panel can be improved.

Further, in the first embodiment, the rib 21b is not formed at a position where it overlaps the drainage grooves 21j and 21k in the vertical direction. As a result, the rib 21b can guide water to the drainage grooves 21j and 21k.

Further, in the first embodiment, the reinforcing portion 41s extending from the bottom surface of the substrate accommodating portion 41 toward the surface member 21 side is formed. As a result, it is possible to prevent the substrate storage portion 41 from being deformed when the foamed heat insulating material is filled.

By the way, the inclined surface 12a1 of the side wall 12a may have a slightly R shape (so as to be convex inward of the refrigerator). In such a case, as a measure against the gap, it is preferable that the substrate storage portion 41 also has an R shape. Therefore, in the second and third embodiments shown below, it is not necessary to give the substrate storage portions 61 and 81 an R shape by making the mounting portions of the storage portions 61 and 81 on the side wall 12a flat. become.

(Second Embodiment)
FIG. 9 is a schematic view showing the positional relationship between the operation panel of the second embodiment and the heat insulating box body.

As shown in FIG. 9, in the refrigerator 1B of the second embodiment, a concave step portion 12m is formed on the inclined surface 12a1 of the side wall 12a. The stepped portion 12m has a rectangular tubular body 12m1 extending from the opening of the side wall 12a toward the side plate 11a, and an annular portion 12m2 extending inward from the tip of the tubular body 12m1. There is. The annular portion 12m2 is formed substantially parallel to the vacuum heat insulating material 50. In other words, the annular portion 12m2 is formed substantially parallel to the side plate 11a. Further, the stepped portion 12m is a side wall 12a having a protrusion amount (dimension) on the front side smaller (smaller) than a protrusion amount (dimension) on the back side in the protrusion amount on the back surface side.

The front surface member 51 has a rib 52 that protrudes toward the back surface side, and the tip of the rib 52 is in contact with the surface of the brim portion 12 m2.

The board accommodating portion 61 is configured to include a recess 62 for accommodating the control substrate 31, and a brim portion 63 formed at the opening edge of the recess 62. The back surface 62c of the recess 62 is formed substantially parallel to the vacuum heat insulating material 50. The brim portion 63 is in contact with the annular portion 12 m2.

In the second embodiment, since the back surface 62c of the substrate storage portion 61 and the vacuum heat insulating material 50 can be made substantially parallel, the gap S1 between the back surface 62c and the vacuum heat insulating material 50 can be made uniform. Further, in the surface member 51 of the second embodiment, the front side is formed so as to protrude inward from the inclined surface 12a1 of the side wall 12a rather than the back side. As a result, the gap between the vacuum heat insulating material 50 and the back surface 62c (back surface of the operation panel 20) of the substrate storage unit 61 can be reduced. By making the gap small in this way, the thickness dimension of the vacuum heat insulating material 50 can be increased, and the heat insulating property of the refrigerator 1A can be improved. Further, in the second embodiment, since the gap between the substrate storage portion 61 and the vacuum heat insulating material 50 can be reduced, the wall thickness of the refrigerator 1A can be reduced (the distance between the side plate 11a and the side wall 12a can be shortened). By reducing the wall thickness of the refrigerator 1A, the internal capacity of the refrigerator compartment 2 can be increased.

(Third Embodiment)
FIG. 10 is a schematic view showing the positional relationship between the operation panel of the third embodiment and the heat insulating box body.

As shown in FIG. 10, the refrigerator 1C of the third embodiment has a convex stepped portion 12p formed on the inclined surface 12a1 of the side wall 12a. The stepped portion 12p has a rectangular tubular body 12p1 extending inward from the opening of the side wall 12a, and an annular portion 12p2 extending inward from the tip of the tubular body 12p1. .. The annular portion 12p2 is formed substantially parallel to the vacuum heat insulating material 50. In other words, the annular portion 12p2 is formed substantially parallel to the side plate 11a. Further, the stepped portion 12p has a protrusion amount (dimension) on the front side larger (larger) than the protrusion amount (dimension) on the back side in the protrusion amount on the front surface side of the side wall 12a.

The front surface member 71 has a rib 72 that protrudes toward the back surface side, and the tip of the rib 72 is in contact with the surface of the annular portion 12p2.

The board accommodating portion 81 is configured to include a recess 82 for accommodating the control substrate 31, and a brim portion 83 formed at the opening edge of the recess 82. The back surface 82c of the recess 82 is formed substantially parallel to the vacuum heat insulating material 50. The brim portion 83 is in contact with the annular portion 12p2.

In the third embodiment, since the back surface 82c of the substrate storage portion 81 and the vacuum heat insulating material 50 can be made substantially parallel, the gap S2 between the back surface 82c and the vacuum heat insulating material 50 can be made uniform. Further, in the second embodiment, the surface member 71 is formed so that the front side protrudes from the side wall 12a to the inside of the refrigerator rather than the back side. As a result, the same effect as that of the second embodiment can be obtained.

In the second embodiment, the side wall 12a has a concave shape, and in the third embodiment, the case where the side wall 12a has a convex shape has been described as an example. However, the side wall 12a is simply attached without being concave or convex. The configuration may be such that the portion is flat.

By the way, when the gap between the substrate storage portion 41 (hereinafter referred to as a case) and the outer plate (side plate 11a) is made small, in the gap between the case and the vacuum heat insulating material 50, urethane (urethane (hereinafter referred to as a case)) Although foam heat insulating material) is included, it is assumed that urethane does not enter near the center. Further, as the operation panel 20 becomes multifunctional, the control board 31 becomes large, and the case for accommodating the control board 31 also becomes large, and is easily affected by the foaming pressure at the time of urethane filling. The relationship between the foaming pressure and the urethane density is shown in FIG. 11 (a). That is, since the urethane density increases when the gap is made small, the foaming pressure increases as the urethane density increases. This causes problems such as damage and deformation of parts such as the case. Therefore, in order to avoid such a problem, the urethane density (ρ) satisfies the following relational expression 1, and a refrigerator using urethane having a density satisfying this equation is used.

Ln (ρ) ≤1066.7 × K / A-17.48 ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ (Equation 1)
ρ: Urethane density (kg / mm ³ )
K: Case rigidity (N / mm)
A: Installation area between urethane and case that has entered the back of the case (mm ² )
As shown in FIG. 11B, the case rigidity K is such that a load F is applied to the case while supporting all of the outer peripheral portion of the case and the protrusions inside the case, and (load F: N) / (deformation amount). It is a numerical value obtained by R: mm).

In a structure like the present embodiment, the heat insulating portion becomes thin depending on the case, the thickness of urethane tends to decrease, and the urethane density tends to increase. Therefore, in this embodiment, it is assumed that the urethane density is 45 kg / m ³ or more.

Next, the basis of Equation 1 will be explained. From the relationship between the density (ρ: kg / mm ³ ) and the foaming pressure (P: MPa), the amount of deformation due to foaming can be expressed by the left side of the following (Equation 2). According to the experimental results conducted by the inventors, the relationship between the urethane density and the foaming pressure shows a tendency as shown in FIG. 11 (a). Further, in order to prevent damage to parts such as a case from urethane foam pressure, it is necessary to satisfy the relationship of (Equation 2).

[Foam pressure] x [Area] / [Case rigidity] ≤ [Allowable value] ... (Equation 2)
Assuming that the gap between the case and the vacuum heat insulating material is about 1.0 mm, the urethane density is generally about 500 × 10 ^ 9 kg / mm ³ . The foaming pressure (MPa) in this case was calculated from the relational expression obtained in FIG. 11A, the case rigidity K was obtained by CAE analysis, and the permissible value corresponding to the right side of (Equation 2) was determined. In addition, it is assumed that the size will be doubled due to the multifunctionalization of the operation panel in the future, and the case rigidity K is expected to be reduced to 1/4 due to material changes, etc., and the allowable value needs to be about 8 times. I think. Therefore, the safety factor is set to 8.
(Equation 1) is derived from the relational expression (Equation 2) obtained in FIG. 11 (a) and the allowable value in consideration of the safety factor described above, and the conditional expression of urethane density against damage or deformation of the case. It becomes.

When the wall thickness of the heat insulating box 10 is reduced, the gap between the case and the vacuum heat insulating material is inevitably narrowed. For example, when the gap is less than 10 mm, the urethane density is high, so that the foaming pressure is high and the urethane is easily deformed. Therefore, a refrigerator is provided in which urethane (foam heat insulating material) does not intervene at least near the center between the case (board storage unit 41) for storing the board (control board 31) and the outer plate (or vacuum heat insulating material 50). By doing so, the deformation due to the foaming pressure can be suppressed, and the space required to provide a margin can be saved.

Further, as shown in FIG. 12, an intervening member 90 may be provided between the case (board storage portion 41) and the vacuum heat insulating material 50. The intervening member 90 is a member that suppresses or prevents the infiltration of the foamed heat insulating material, and a sponge-like material such as soft urethane, styrofoam, or the like can be applied. Further, if the distance between the case and the vacuum heat insulating material 50 is set as narrow as 6 mm or less, the foamed heat insulating material is less likely to enter between the case and the vacuum heat insulating material 50.

Further, by providing the intervening member 90, the case and the vacuum heat insulating material 50 do not come into direct contact with each other, so that leakage of the vacuum heat insulating material 50 can be prevented. Further, the intervening member 90 may be a compressible member that closes the gap between the case and the vacuum heat insulating material 50 (a member that is larger than the original size of the gap and intervened). As the compressible member, Styrofoam and polyethylene foam can be applied. Further, the intervening member 90 is preferably one in which the foamed heat insulating material does not penetrate.

The present invention is not limited to the above-described embodiment, and includes various modifications. For example, in the present embodiment, the case where the operation panel 20 is provided on the inclined surface 12a1 of the side wall 12a in the refrigerator has been described, but it may be applied to the top wall 12d in which the interior light is provided. Alternatively, it may be applied to the place where the main board on the upper surface of the refrigerator is mounted. Alternatively, it may be applied to a place where an IOT (Internet of Things) board is mounted.

1A, 1B, 1C Refrigerator 10 Insulated box body 11 Outer box 12 Inner box 12a Side wall (side)
12a1 Inclined surface 12m, 12p Stepped part 20 Operation panel (unit member)
21 Surface member 21b Rib 21e Upper rib 21e1,21e2 Inclined path 21e3 Inclined surface 21f, 21g Side rib 21h, 21i Lower rib 21j, 21k Drainage groove 21t Recessed 31 Control board (circuit board)
31b Upper side 31c Side side 31d Lower side 41 Board storage 41s Reinforcing part 41s1 Tip 42c Back side (face facing the outer box)
50 Vacuum heat insulating material

Claims (4)

A unit member having a front surface member, a circuit board provided on the back surface side of the front surface member, and a substrate storage portion for accommodating the circuit board and fixing the surface member.
A heat insulating box body is provided between the inner box and the outer box, and the unit member is arranged on at least one of the left and right sides of the inner box.
On the back surface of the front surface member, a drainage groove is formed at the lower end in the vertical direction .
A refrigerator having ribs located on the upper side of the circuit board, and the upper surface of the ribs has an inclined surface that descends from the back surface side to the front surface side of the front surface member . The refrigerator according to claim 1 , wherein the upper surface of the rib located on the upper side portion has a ramp that slopes downward from the center in the width direction toward both sides in a front view. A unit member having a front surface member, a circuit board provided on the back surface side of the front surface member, and a substrate storage portion for accommodating the circuit board and fixing the surface member.
A heat insulating box body is provided between the inner box and the outer box, and the unit member is arranged on at least one of the left and right sides of the inner box.
On the back surface of the front surface member, a drainage groove is formed at the lower end in the vertical direction .
A refrigerator characterized in that a reinforcing portion extending from the bottom surface of the substrate storage portion toward the surface member side is formed . A unit member having a front surface member, a circuit board provided on the back surface side of the front surface member, and a substrate storage portion for accommodating the circuit board and fixing the surface member.
A heat insulating box body is provided between the inner box and the outer box, and the unit member is arranged on at least one of the left and right sides of the inner box.
On the back surface of the front surface member, a drainage groove is formed at the lower end in the vertical direction .
Ribs extending downward from the upper side portion of the circuit board through the left and right side sides are formed on the back surface of the front surface member.
While the ribs are not formed at least in the portion where the drainage groove is located,
In the vicinity of the portion having the drainage groove, claws protruding from the back surface of the front surface member to the outside of the refrigerator and locking the edge portion of the circuit board are separated from each other in the front-rear direction at a position not blocking the drainage groove. A refrigerator characterized by being formed to do so .

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