KR20110011502A - Refrigerator - Google Patents

Abstract

PURPOSE: A refrigerant which includes light emitting diodes arranged in the predetermined array structure is provided to improve visibility by equalizing the light intensity of inside of the refrigerant. CONSTITUTION: A refrigerant comprises a cold room(2), a door(6b), a door pocket(11), a plurality of inner shelves, a plurality of light emitting diodes, and a reflecting mirror(14). The door opens and closes a front opening of a cold room. The door pocket is installed in the inner top and bottom of the door and accepts food. The inner shelf is installed on top and bottom of the cold room, and the food is put on.

Description

Refrigerator {REFRIGERATOR}

The present invention relates to a refrigerator.

Conventionally, since a refrigerating compartment, which is a storage space installed in a refrigerator, has a large volume and a high frequency of use, a plurality of lighting devices in the refrigerator are dispersed and installed in order to brightly illuminate the entire interior of the refrigerating compartment in order to improve user visibility. there was. However, in such a configuration, it is disadvantageous in terms of power saving and has a high cost.

Therefore, in recent refrigerators, light emitting diodes (hereinafter referred to as "LEDs") with a small amount of power consumption are employed as lighting devices in the refrigerator.

Patent Literature 1 describes a configuration in which a lighting device made of LED is provided on a ceiling inside a refrigerator, and a cooling panel made of metal such as aluminum is provided on the rear surface of the refrigerator. By this structure, while improving the cooling efficiency in a refrigerator, the surface of a cooling panel is mirror-finished, and the light emitted by a lighting device is reflected in the whole refrigerator, and the lighting effect is improved.

Japanese Patent Publication No. 2009-47360

However, in the structure of patent document 1, a lighting apparatus is located in the center of the width direction of the ceiling surface in a refrigerator, and the cooling panel of substantially the same width as a lighting apparatus is provided over almost the full width of the back surface in a refrigerator. The light emitting diode has a higher light directivity than a conventional light bulb, but has a narrow irradiation angle. Accordingly, there has been a problem that the entire interior of the refrigerator cannot be uniformly lit by a few LEDs.

Moreover, in the case of the food mounted in the left and right both ends of the shelf provided in the refrigerator, the upper surface and one side surface are reflected by light. On the other hand, in the case of the food loaded near the center of the shelf in the refrigerator, only its upper surface shines with light. For this reason, there existed a problem that the food loaded in the center of a refrigerator looks visually dark compared with the food loaded in both sides of a refrigerator.

In addition, when a cooling panel is attached to the entire width of the rear surface of the refrigerator, and the light irradiated to the rear is reflected in the front, the illuminance of both ends of the refrigerator and the center of the refrigerator increases evenly. As a result, there has been a problem that the center in the refrigerator is visually dark.

In view of the above problems, an object of the present invention is to obtain a refrigerator in which the illuminance in the refrigerator is equalized and the visibility is improved.

MEANS TO SOLVE THE PROBLEM In order to solve the said subject, this invention provides the refrigerator compartment formed in the refrigerator main body, the door which opens and closes the front opening of the said refrigerator compartment, and the door pocket which accommodates food in multiple numbers installed in the up-down direction inside the refrigerator compartment of the said door. And a plurality of shelves in the refrigerator, in which a plurality of refrigerators are installed in the vertical direction of the refrigerating compartment, in which food is loaded, a plurality of light emitting diodes disposed in the front and rear rows in the depth direction of the upper surface of the refrigerating compartment, and the rear of the refrigerating compartment. And a reflective member provided at the rear of the shelf in the refrigerator, wherein the light-emitting diode of the heat transfer is located above the gap between the front end of the shelf in the refrigerator and the end face of the door pocket. Or it is installed so as to be located ahead of the gap, the rear row light emitting diode is the cold of the uppermost within the irradiation angle of the light emitting diode And is installed on the shelf in the rear end position (後方 端) include the width of the reflection member is characterized in that less than with a plurality of the LED layout width.

The rear row light emitting diode is inclined toward the rear side of the refrigerating compartment.

A refrigerator compartment formed in the refrigerator main body, a door for opening and closing the front opening of the refrigerator compartment, a door pocket provided in a plurality of up and down directions of the door, a shelf in the refrigerator provided in a plurality of the refrigerator compartment, and an upper surface of the refrigerator compartment in the front-rear direction A light emitting diode having a plurality of rows is provided, the heat transfer of the light emitting diode is located in front of the front end of the shelf in the refrigerator, the rear row of the light emitting diode is located above the shelf in the refrigerator, the irradiation angle of the light emitting diode And a rear end of the shelf in the refrigerator at the top end thereof.

This invention aims at equalizing the illuminance in a refrigerator and can obtain the refrigerator which improved visibility.

1 is a front view of a refrigerator according to Embodiment 1 of the present invention.
FIG. 2 is a view excluding a door of the refrigerator of FIG. 1, illustrating a irradiation range in a width direction of a lighting device in the refrigerator.
3 is an AA longitudinal cross-sectional view of FIG. 1, illustrating a irradiation range in a depth direction of a lighting device in a refrigerator.
4 is a sectional view of a main portion of a refrigerator according to a second embodiment of the present invention;
5 is an explanatory diagram of a light emitting substrate constituting a lighting device in a refrigerator according to a third embodiment of the present invention;
6 is an explanatory diagram of a light emitting substrate constituting a lighting device in a refrigerator according to a fourth embodiment of the present invention;
7 is a view for explaining an attachment structure of a mounting substrate according to a fifth embodiment of the present invention.
8 is a view taken from the direction of arrow P, with the irradiation cover removed from the lighting device in the refrigerator shown in FIG.
9 is a view showing a detailed structure of the elastic claw shown in FIG.

EMBODIMENT OF THE INVENTION Hereinafter, the Example of this invention is described, referring drawings.

Example 1

1 is a front view of a refrigerator according to Embodiment 1 of the present invention. FIG. 2 is a view excluding a door of the refrigerator of FIG. 1, illustrating a irradiation range in a width direction of a lighting device in the refrigerator. 3 is a cross-sectional view taken along line A-A of FIG. 1, illustrating a irradiation range in a depth direction of a lighting device in a refrigerator.

1 to 3, the refrigerator main body 1 has a refrigerating chamber 2, a second freezing chamber 3, a freezing chamber 4, and a vegetable chamber 5 from above. In the front opening of the refrigerating compartment 2, a left refrigerating compartment door 6a and a right refrigerating compartment door 6b are provided, and the French door for opening and closing the refrigerating compartment 2 by rotating through the upper and lower hinges, respectively. Configure. In each front opening of the 2nd freezer compartment 3, the freezer compartment 4, and the vegetable compartment 5, the 2nd freezer compartment door 7, the freezer compartment door 8, and the vegetable compartment door 9 are opened so that each opening can be opened and closed. Equipped. In addition, the 2nd freezer compartment door 7, the freezer compartment door 8, and the vegetable compartment door 9 are pull-out doors which move back and forth.

The shelf 10 in the refrigerator provided in multiple stages in the up-down direction in the refrigerating chamber 2 is comprised from the transparent resin material. Accordingly, when food is not stored on the shelf 10 in the refrigerator, the light of the lighting in the refrigerator to be described later is transmitted from the upper surface to the lower surface direction.

In the refrigerator compartment 2 side of the left refrigerator compartment door 6a and the right refrigerator compartment door 6b, the door pocket 11 is provided in multiple steps in the up-down direction so as to oppose the shelf 10 in a refrigerator. This door pocket 11 also consists of a transparent resin material, and transmits the light of the illumination in the refrigerator described later from one side to the other side.

The code | symbol G shown in FIG. 3 represents the clearance gap provided in the shelf front end 10a and the door pocket cross section 11a in a refrigerator. When the left and right refrigerating chamber door 6a or the right refrigerating chamber door 6b is opened and closed, this clearance gap G is the inside of the refrigerator of the door pocket 11 and the thing (bucket or bottle etc.) in this door pocket 11. It is a gap provided in order to prevent contact with the shelf tip 10a.

Next, the refrigerator inner side of the refrigerator compartment 2 is equipped with the refrigerator compartment panel 12 which guides cold air so that the whole refrigerating compartment 2 may be cooled by the cold air introduce | transduced into the refrigerator compartment 2. As shown in FIG. 3, the refrigerating chamber panel 12 has a plurality of cold air jet ports 13 in the vertical direction. Thereby, cold air is blown off corresponding to the height of each shelf 10 in a refrigerator, and cooling efficiency can be improved.

The reflection member 14 is provided in the front surface of the refrigerator compartment panel 12. The reflective member 14 has the cold air jet port 14a at the location corresponding to the cold air jet port 13. The reflecting member 14 is made of a material having high thermal conductivity such as thin plate-shaped aluminum, stainless steel, or resin. In addition, the surface of the reflective member 14 serves to reflect light, and also contributes to cooling in the refrigerating chamber 2. And the dimension of the width direction of the reflecting member 14 is made smaller than the width dimension of the lighting apparatus 15 in the refrigerator mentioned later, and the dimension of an up-down direction is provided only over two steps of the center part of the refrigerator shelf 10. It is. In the case of this embodiment, it is located in the substantially center of the width direction of the shelf 10 in a refrigerator across the shelf in the refrigerator of the 2nd step | paragraph and the 3rd step | paragraph.

The lighting apparatus 15 in a refrigerator is comprised by the mounting board 17 in which the light emitting diode 16 was mounted, the cover 18, etc. This in-fridge lighting apparatus 15 is attached to the recessed part which made the ceiling surface 19 of the refrigerating chamber 2 to the heat insulating material 20 side, as shown in FIG.

The light emitting diodes 16 are arranged on the mounting substrate 17 in four rows in the horizontal width direction of the ceiling surface 19 at a 45 mm pitch and two rows in the ceiling surface 19 depth direction. That is, eight pieces are provided in total of the front row 16a and the rear row 16b.

In addition, the light emitting diode 16 should just be arrange | positioned 2 or more rows in the depth direction of the surface of the mounting board 17, It does not specifically limit about the number provided in the width direction of the mounting board 17. As shown in FIG. The light emitting diode 16 in this embodiment has a large irradiation angle, for example, about 120 degrees.

The light emitting diodes 16 of the heat transfer 16a are attached to face the gap G or to be located ahead of the gap G, and are positioned above the inside of the refrigerating chamber 2 as shown in FIG. 3.

The light emitting diode 16 of the rear row 16b is located above the shelf 10 in the refrigerator, and directs light to the rear part of the shelf 10 in the uppermost refrigerator. In other words, in order for the light of the light emitting diode 16 with an irradiation angle of 120 degrees to reach the rear end of the shelf 10 in the refrigerator, the position of the light emitting diode 16 in the rear row 16b or the inside of the refrigerator. The depth dimension of the shelf 10 becomes a problem. In this embodiment, the irradiation angle of the light emitting diode 16, the depth dimension of the shelf 10 in the refrigerator, and the positional relationship of the light emitting diode 16 on the rear row 16b side are determined to the last end of the shelf 10 in the refrigerator. It is equipped to investigate appropriately.

As mentioned above, although the depth direction of the shelf 10 in a refrigerator was demonstrated by the illuminating device 15 in the refrigerator, the example which irradiates the left-right direction of the shelf 10 in a refrigerator is demonstrated, referring FIG. .

The refrigerator of this embodiment has a width W dimension of 650 mm or more and a depth D dimension of 600 mm or more. Therein, in order to direct light to the entire upper shelf 10 in the refrigerator, the lighting device 15 in the refrigerator has the predetermined width as shown in FIG. 2 (the ceiling surface ( The light irradiated from the light emitting diodes 16 of the both ends is arrange | positioned to the edge part of the width direction of the shelf 10 in a refrigerator. As a result, light reaches the food loaded on both ends of the shelf 10 of the uppermost refrigerator 10, and the visibility can be improved.

Next, the example which illuminates the food stored in the 2nd and 3rd stage inside from the shelf 10 in a refrigerator is demonstrated.

In the conventional refrigerator, the light of the lighting in the refrigerator is blocked by the food loaded on the shelf 10 in the uppermost refrigerator and the food loaded in front of the shelves in the second and third stages of the refrigerator. Then, the back of the shelf in a refrigerator becomes dark and there exists a possibility that visibility may fall. In addition, the distribution (viewed from the front of the refrigerator compartment) of the food stored in the shelves in the refrigerators of the second and third stages is a location where light does not reach, and the inside of the refrigerator is darkened.

Therefore, in the present embodiment, the lighting device 15 in the refrigerator is provided on the ceiling surface 19, and light is irradiated from above from the food loaded in the vicinity of the center of the shelf 10 in the refrigerator. On the other hand, the food loaded on both the left and right sides of the shelf 10 in the refrigerator is visually bright even in the food loaded in the center because light is irradiated not only on the top but also on the side.

In the case of the refrigerator of this embodiment, the light irradiated from the lighting device 15 in the refrigerator is not completely blocked by the stored food, and the reflection member 14 provided inside the second and third stages through the foods. To reach. The light which has reached is the structure which reflects the food which was reflected by the reflecting member 14, and was loaded in 2nd and 3rd stage inside from the back side inside a refrigerator.

That is, according to this embodiment, since illumination is also provided from the distribution of the stored food, the whole food is reflected and the visibility is improved. This prevents the user from forgetting the food stored in the inside of the shelf 10 of the second and third stage refrigerators, and contributes to the promotion of the use of the stored food.

In addition, the dimension of the width direction of the reflective member 14 is smaller than the dimension of the width direction of the lighting apparatus 15 in a refrigerator. This means that if the width dimensions of the reflecting member 14 and the lighting device 15 in the refrigerator are equal, the irradiated light is reflected at the entire width of the reflecting member 14 so that the inside of the refrigerator is evenly brightened, and the center part of the refrigerator is visually visible. Because it looks dark.

That is, the food loaded on the left and right sides of the shelf 10 in the refrigerator by the light (irradiation angle is about 120 degrees) irradiated from the lighting device 15 in the refrigerator provided near the center of the width direction of the ceiling in the refrigerator, Mainly the upper surface and one side of the food are inclined from the upper side to reflect. On the other hand, the food loaded in the vicinity of the center of the shelf 10 in the refrigerator mainly reflects the upper surface from almost immediately above. From this, the food loaded near the center is visually dark compared with the food loaded on both the left and right sides of the shelf 10 in the refrigerator.

In this embodiment, by making the width dimension of the reflection member 14 smaller than the width dimension of the lighting device 15 in the refrigerator, the light reflected by the reflection member 14 is mainly located near the center of the shelf 10 in the refrigerator. Concentrate on the loaded food. As a result, the food near the center of the shelf 10 in the refrigerator is reflected not only from above but also from the rear, and closer to the brightness of the food loaded on both the right and left sides. That is, the brightness of the food loaded on the central portion of the shelf 10 in the refrigerator and the food loaded on one side of the left and right sides of the shelf 10 in the refrigerator is equalized, so that the user can easily see it visually.

Next, the example which irradiates the food stored in the front and door pocket 11 of the shelf 10 in a refrigerator is demonstrated. The light emitting diode 16 located in the heat transfer 16a of the lighting device 15 in the refrigerator is located directly above the gap G or in front of the gap G. The food stored in the front and door pocket 11 of the shelf 10 in a refrigerator is reflected by the light of the light emitting diode 16 which progresses directionally from upper to downward in the vicinity of the gap G. That is, part of the light irradiated from the light emitting diodes 16 irradiates the food stored in the front of the shelf 10 in the uppermost refrigerator and the uppermost door pocket 11, and the remaining light goes straight downward. Then, the food stored in the front of the shelf 10 in the second stage and the door pocket 11 in the second stage is irradiated, and the remaining light goes straight downward. And it is a structure which irradiates the food stored in the front of the shelf 10 in the 3rd stage refrigerator, and the door pocket 11 of the 3rd stage.

About the refrigerator comprised as mentioned above, the illumination of the food loaded on the shelf 10 in a refrigerator is demonstrated. The cold air jetted into the refrigerating chamber 2 cools the entire inside of the refrigerating chamber 2. In addition, the reflective member 14 indirectly cools the food around the reflective member 14. In addition, the reflective member 14 is cooled to low temperature compared with the other by cold air which cools the refrigerating chamber 2. On the other hand, when the left refrigerating compartment door 6a or the right refrigerating compartment door 6b is opened, the lighting device 15 in the refrigerator turns on. And the lighting device 15 in a refrigerator functions to illuminate the whole area in the refrigerating chamber 2.

Light emitted from the light emitting diodes 16 of the rear row 16b constituting the in-fridge lighting device 15 directly reflects the rearmost end of the shelf 10 in the refrigerator and both side ends in the width direction. Moreover, it reflects to the reflection member 14 located in the 2nd and 3rd stage back of the shelf 10 in a refrigerator, and indirectly illuminates food from the back side inside a refrigerator. In addition, the light emitting diode 16 of the heat transfer 16a irradiates light toward the front and door pocket 11 of the shelf 10 in the refrigerator via the gap G. Accordingly, the lighting device 15 in the refrigerator can brightly illuminate the entire refrigerating chamber 2 and allow the user to recognize the position of the stored food.

The position of the up-down direction of the reflective member 14 is located in the back of the shelf 10 in the refrigerator of 2nd stage and 3rd stage. In addition, when the shelf 10 of the refrigerator is detachable and the refrigerator can be freely adjusted by the user, the uppermost shelf of the refrigerator may be moved by moving the attachment position of the upper shelf 10 of the refrigerator downward. The reflecting member 14 is located behind 10.

As described above, the present embodiment, as well as the front of the door pocket 11 and the shelf 10 in the refrigerator, especially the upper part of the refrigerator, the rear of the shelf 10 in the refrigerator, the back surface of the refrigerator, etc. Material becomes clear and improves visibility.

[Example 2]

4 is a sectional view of a main portion of a refrigerator according to a second embodiment of the present invention. The light emitting diode 16 of the rear row 16b of the mounting board 17 constituting the in-fridge lighting device 15 has the heat insulating material 20 side toward the rear so as to illuminate the rear part of the shelf 10 of the uppermost refrigerator. It is installed inclined toward. Thereby, the light of the light emitting diode 16 which has an irradiation angle of 120 degree | times becomes easy to reach the rear part of the shelf 10 in the refrigerator of the uppermost stage.

In the refrigerator configured as described above, the light emitted from the light emitting diode 16 illuminates the rear image of the shelf 10 in the refrigerator as long as the mounting substrate 17 is inclined (by the L1 dimension shown in FIG. 4). Thereby, the visibility of the stored food on the shelf 10 in a refrigerator improves.

As described above, according to the refrigerator of the second embodiment, when the amount of stored food is small, the stored food in the uppermost rear inner part of the refrigerating compartment 2 can be effectively illuminated without being blocked by the stored food.

Example 3

5 is an explanatory diagram of a light emitting substrate constituting a lighting device in a refrigerator according to a third embodiment of the present invention. The mounting board 17 inclines the light emitting diode 16 of the back row 16b among the light emitting diodes 16 of the heat transfer 16a and the back row 16b in the back direction inside the refrigerator.

In the refrigerator configured as described above, the light emitted from the light emitting diode 16 illuminates the rear of the shelf 10 in the refrigerator as much as the light emitting diode 16 of the rear row 16b is inclined. Thereby, the visibility of the stored food on the shelf 10 in a refrigerator improves.

Example 4

6 is an explanatory diagram of a light emitting substrate constituting a lighting device in a refrigerator according to a fourth embodiment of the present invention. The mounting board 17 divides the mounting board 17 back and forth. Then, the light emitting diode 16 side of the rear row 16b of the divided mounting substrate 17 is inclined to the heat insulating material 20 side to face the inside direction of the refrigerator.

Alternatively, the mounting board 17 is folded and bent in an approximately L shape without dividing the mounting board 17, and the light emitting diode 16 side of the rear row 16b is inclined to the heat insulating material 20 side, so that the rear surface of the refrigerator is inclined. Facing direction.

As described above, according to the fourth embodiment, sufficient light can be brought to the rear of the refrigerating compartment 2, and the illumination in the refrigerator can be brought into contact with the food stored in the entire refrigerating compartment 2.

Example 5

7 is a view for explaining the attachment structure of the mounting substrate according to the fifth embodiment of the present invention. FIG. 8 is a view taken from the direction of arrow P with the irradiation cover removed from the in-fridge lighting device shown in FIG. 7. 9 is a view showing a detailed structure of the elastic claw shown in FIG. In the present embodiment, like other embodiments, the lighting device 15 in the refrigerator has a light emitting diode 16.

The board | substrate with which the light emitting diode 16 was mounted is divided | segmented back and forth in the refrigerator depth direction, and has the heat-transfer mounting board 17a and the post-heat mounting board 17b. As for the heat transfer mounting board 17a and the post-heat mounting board 17b, the light-emitting diode 16 of the heat transfer 16a and the back row 16b is respectively provided.

The heat transfer mounting board 17a and the post heat mounting board 17b are the front elastic claw 29 and the rear elastic claw which are fixing means provided in the ceiling surface 21a of the board | substrate accommodating part 21 ( Respectively). In the board | substrate accommodating part 21, the cover 18 is provided in the refrigerator inside, and the board | substrate accommodating part 21 fills in the recessed part formed by making the ceiling surface 19 concave toward the heat insulating material 20 side, and forming it. It is installed to build.

The board | substrate accommodating part 21 has the magnitude | size which can attach the heat-transfer mounting board 17a and the post-heat mounting board 17b, and the board | substrate accommodating part 21 in the space which made the heat insulating material 20 concave. Part of is attached to be filled in. Moreover, the ceiling surface 21a of this board | substrate accommodating part 21 is comprised so that it may become substantially parallel with the ceiling surface 19 of the refrigerating chamber 2. As shown in FIG. In addition, the size of this board | substrate accommodating part 21 is made into the depth dimension L2 required for irradiating the board | substrate 2 divided | segmented into the 2nd-part mounted board | substrate in the whole refrigerating chamber 2, as demonstrated in the Example mentioned above.

The rear elastic claw 22 and the front elastic claw 29 may be integrally formed with the substrate storage portion 21. When integrally comprised, the board | substrate accommodating part 21 can be comprised by resin material, and the back elastic claw 22 and the front elastic claw 29 can be shape | molded simultaneously. As shown in FIG. 9, the rear elastic claw 22 and the front elastic claw 29 have the heat-transfer mounting board 17a and the post-heat mounting board 17b with the ceiling surface 21a of the board | substrate accommodating part 21. As shown in FIG. It has the holding part 23 hold | maintained in between. Moreover, this rear elastic claw 22 has the hook part 22a at the front end, and prevents the heat-transfer mounting board 17a and the post-heat mounting board 17b affixed to the holding | maintenance part 23 from falling off. Moreover, the hook part 22a of the rear elastic claw 22 and the front elastic claw 29 opens the opening part 24, making the base part 22b the point like the broken line of FIG. The board | substrate 17 is inserted in the holding | maintenance part 23 in the arrow P1 direction, and affixed.

As shown in FIG. 8, this rear elastic claw 22 and the front elastic claw 29 are provided in the board | substrate accommodating part 21 so that the opening part 24 may mutually oppose with the space | interval L1. This space | interval L1 is comprised larger than the width | variety dimension W of each of the heat-transfer mounting board 17a and the post-heat mounting board 17b, and the heat-transfer mounting board 17a and the post-heat mounting board 17b are space | interval L1. Assembled in the holding portion 23 through the), it is configured to be separated.

The dimension L3 between the heat-transfer mounting board 17a and the post-heat mounting board 17b attached to the rear elastic claw 22 and the front elastic claw 29 and the shelf 10 in the refrigerator becomes an important dimension. That is, when the L3 dimension (height distance between the uppermost shelf 10 in the refrigerator and the lighting device 15 in the refrigerator) shown in FIG. 7 becomes small, the light emitting diodes on the heat transfer board 17a and the post heat mount board 17b are reduced. The range (dimensions in the depth direction and the width direction) that can be irradiated changes. Therefore, as a design not to reduce the L3 dimension by attaching the lighting device 15 in the refrigerator, in the present embodiment, a part of the substrate accommodating portion 21 is embedded in the heat insulating material 20 side, and the substrate accommodating portion is provided. The holding part 23 is provided between the ceiling surface 21a of 21. As shown in FIG.

In addition, since the direction in which the post-heat-mounting substrate 17b is inserted into the rear elastic claw 22 is the arrow P1 direction, the height dimension L4 (see FIG. 9) of the elastic claw can be reduced. That is, in the method of inserting one mounting substrate 17 from the bottom between a pair of opposing substantially L-shaped elastic claws and an approximately inverted L-shaped elastic claw, elastic deformation of the elastic claws is required. Therefore, the size of L4 must be increased, and the height of the lighting device 15 in the refrigerator is increased.

In this embodiment, the heat-transfer mounting board 17a and the post-heat mounting board 17b each have a structure in which they are inserted in the horizontal direction into the L-shaped rear elastic claws 22 and the front elastic claws 29, respectively, so as to have a refrigerator. It is possible to attach, without increasing the dimension of the up-down height direction of the internal lighting apparatus 15. FIG.

In addition, although the insertion direction of the electrothermal-mounting board 17a was not shown in figure, it inserts in the opposite direction to arrow P1. This is because the front elastic claw 29 is provided symmetrically with respect to the rear elastic claw 22 in the front-back direction.

Moreover, even in the structure which slides a rectangular mounting board between a pair of opposing L-shaped elastic claws and an inverted L-shaped elastic claw from the short dimension side of a mounting board in the refrigerator inner width direction, it is a refrigerator. It is possible to attach without increasing the dimension of the up-down height direction of the internal lighting device 15. FIG.

In addition, as shown in FIG. 7, the front elastic claw 29 and the rear elastic claw 22b are integrally provided in the ceiling surface 21a of the board | substrate accommodation part so that the opening part 24 may mutually oppose. A gap L1 is provided between the rear elastic claw 22 and the opening portion 24 of the front elastic claw 29. At the time of assembly, the heat-transfer mounting board 17a and the post-heat mounting board 17b are inserted into the holding section 23 in the horizontal direction from each of the front and rear openings 24 by using this gap L1. In other words, the space | interval L1 side is larger than the width | variety dimension W of each of the heat-transfer mounting board 17a and the post-heat mounting board 17b.

Here, the larger the dimension L1 between the rear elastic claw 22 and the front elastic claw 29 is, the wider the irradiation range of the light emitting diode 16 is. For this reason, the rear side elastic claw 22 and the front side elastic claw 29 can obtain the largest irradiation range in consideration that the irradiation angle is 120 degree within the depth dimension L2 of the board | substrate accommodation part 21. Installed at the location.

At the time of opening of the left refrigerator compartment door 6a and the right refrigerator compartment door 6b, the heat transfer 16a mainly illuminates the front part of the shelf 10 in a refrigerator. The left refrigerating compartment door 6a and the right refrigerating compartment door 6b are left and right pairs of opening and closing doors, and if one door is closed, the door pocket 11 is also illuminated. In addition, when one of the doors is closed, there is no object blocking light by passing through the gap G (see FIG. 7), and the front of the shelf 10 and the door pocket 11 in the refrigerator. The lowermost part of the whole stage and the refrigerating chamber 2 can be projected.

After attaching the mounting board 17 to the board | substrate accommodating part 21, the cover 18 which covers the lower opening of the board | substrate accommodating part 21 is provided with the roulette (uneven | corrugated shape) in the surface, Is widening.

As described above, the mounting substrate 17 is divided into the front and rear directions in the depth direction of the refrigerator, and four light emitting diodes 16 are further formed on the heat-transfer mounting substrate 17a, and the four light-emitting diodes are also applied to the post-heat mounting substrate 17b. The diode 16 is provided.

This light emitting diode 16 is included in the main body of the mounting substrate 17, unlike in FIG. Moreover, the irradiation angle of this light emitting diode 16 is also 120 degree | times.

The front connector 25 provided on the heat transfer board 17a side and the rear connector 26 provided on the side of the heat transfer mount board 17b face each other, so that the length of the cable connecting the connectors can be shortened. have. In addition, by connecting with the 4P connector, as shown in Fig. 8, the wiring can be made in one circuit, and the miswiring can be eliminated.

The power cord 27 is a cord for supplying electricity to the heat transfer mounting board 17a and the post heat mounting board 17b through the front connector 25. The power supply cord 27 is drawn out from the cord outlet 28 provided in the board | substrate accommodating part 21 into the board | substrate accommodating part 21 through the inside of the heat insulating material 20. FIG.

In the refrigerator having such a configuration, when the door of the refrigerator compartment 2 is opened, the lighting device 15 in the refrigerator illuminates the inside of the refrigerator compartment 2 as follows. That is, since the light emitting diode 16 of the rear row 16b is configured to irradiate the upper surface of the upper shelf 10 of the refrigerator and the upper surface of both side ends, the stored food stored in the upper shelf 10 of the refrigerator. In this case, light of the light emitting diode 16 is directly in contact.

On the other hand, the reflection member 14 provided in the rear wall of the refrigerating chamber 2 acts on illumination of the inner part of the shelf 10 in the refrigerator other than the uppermost stage like the said Example. That is, when the light irradiated from the lighting device 15 in the refrigerator reaches the reflecting member 14, the light is reflected by the reflecting member 14 to illuminate the inner portion of the shelf 10 in the refrigerator other than the top end. The post-heat mounting board 17b is attached to the position which performs the said action.

In addition, the heat transfer mounting substrate 17a is provided on the gap G provided in the portion where the door pocket 11 and the shelf 10 in the refrigerator face each other, and the light emitted from the heat transfer light emitting diode 16 is The front of the door pocket 11 and the shelf 10 in the refrigerator is examined through the gap G.

Thus, the light emitting diode 16 arrange | positioned in the heat transfer 16a and the back heat 16b improves visibility by illuminating the whole refrigerating compartment 2 in the refrigerating compartment 2 even if the environment in which the refrigerator is installed is dark.

On the other hand, during the inspection and service of the heat transfer mounting board 17a and the post heat mounting board 17b, after removing the cover 18 from the lighting device 15 in the refrigerator, the heat transfer mounting board 17a is first used as an example. In the direction, the hook portion 22a is widened, the opening portion 24 is enlarged, and the heat transfer mounting substrate 17a is separated from the holding portion 23.

Subsequently, the post-heat mounting board 17b is similarly slid in the L1 direction, the hook portion 22a is widened to enlarge the opening 24, and the post-heat mounting board 17b is separated from the holding part 23.

In this case, the front connector 25 and the rear connector 26 are separated from the heat transfer board 17a and the post heat mount board 17b.

Since this invention has the structure as demonstrated above, the following effects are acquired. That is, at a portion where the plurality of door pockets installed and the plurality of shelves in the refrigerator face each other have an interval of about 10 to 50 mm from the top to the bottom, and install a lighting device in the refrigerator on the ceiling surface of the refrigerator, The light emitting diodes were installed in two rows before and after the mounting board constituting the lighting device, the front pockets and the front of the shelf in the refrigerator were irradiated, and the inner portion of the rear of the shelf in the refrigerator was irradiated in the rear row.

According to such a structure, not only the door pocket and the front of a shelf in a refrigerator, but especially the uppermost part of a refrigerator etc. are reflected well, the material of a stored food becomes clear and it is easy to make food in and out.

In addition, the irradiation angle of the light emitting diode is set to 120 degrees, and the lighting device in the refrigerator is provided at a position where the depth direction, the width direction, and all of the uppermost shelves of the refrigerator can be irradiated. According to this structure, especially when the quantity of food stored is small, it can effectively illuminate the food stored on the shelf in the refrigerator at the top of a refrigerating chamber, without disturbing food.

In addition, a metal plate made of a reflecting plate having a width smaller than that of the lighting device in the refrigerator is provided in a cosmetic panel for forming a cold air duct attached to the rear surface of the refrigerator, and the light irradiated from the light emitting diode The reflector is used to direct the light to the food in the inner part of the shelf in the second and third stage refrigerators from the top.

According to such a structure, even if the light of the lighting device in the refrigerator is disturbed by the stored food or the like and is not directly illuminated from above, since the light can be indirectly emitted from the rear through the metal plate, the stored food is not seen.

In addition, the width dimension of the metal plate used as a reflecting plate is less than the width | variety of the lighting apparatus in a refrigerator, and the vertical dimension is made into two or less steps of shelves in a refrigerator. According to such a structure, light can be made to contact the food stored in the place where the light from the above is hard to reach, and it can serve as a design effect, and can use it as an effective method of using a metal plate.

In addition, the mounting substrate with the post-heat light emitting diode is inclined so that the light reaches the rear side of the refrigerating chamber, and the light is easily reached at the end of the depth direction at the top end of the shelf in the refrigerator. According to such a structure, in particular, sufficient light can be led to the rear of a refrigerator compartment, and the lighting in a refrigerator can be made to contact the food stored in the whole refrigerator compartment.

1: refrigerator body 2: refrigerating chamber
6a: left fridge door 6b: right fridge door
10: shelf in the refrigerator 11: door pocket
12: refrigerator compartment panel 13, 14a: cold air outlet
14: reflection member 15: lighting device in the refrigerator
16: light emitting diode 16a: heat transfer
16b: Post-heat 17a: Electrothermal Mounting Substrate
17b: post-heat-mounting substrate 18: cover
19: ceiling surface 20: insulation
21: substrate storage portion 21a: ceiling surface
22: rear elastic claw 22a: hook portion
23: holding portion 24: opening
25: front connector 26: rear connector
27: power cord 28: cord outlet
29: front elastic claw

Claims (3)

A refrigerator compartment formed in the refrigerator main body,
A door for opening and closing the front opening of the refrigerating compartment,
A plurality of door pockets installed in a vertical direction inside the refrigerating chamber of the door to accommodate food;
Shelf in the refrigerator which is installed in a plurality of up and down direction of the refrigerating compartment for loading food,
A plurality of light emitting diodes disposed in the front and rear rows in the depth direction of the upper surface of the refrigerating chamber,
A reflection member provided at the rear of the refrigerator compartment and at the rear of the shelf in the refrigerator;
The heat-emitting light emitting diode is provided so as to be located above the gap between the front end of the shelf in the refrigerator and the end face of the door pocket, or in front of the gap.
The rear row light emitting diode is provided at a position including a rear end of the shelf in the refrigerator at the top end within an irradiation angle of the light emitting diode,
And a width of the reflective member is smaller than a width of the plurality of light emitting diodes. The method of claim 1,
And the rear row light emitting diode is inclined toward the rear side of the refrigerating compartment. A refrigerator compartment formed in the refrigerator main body,
A door for opening and closing the front opening of the refrigerating compartment,
Door pockets provided in plural in the vertical direction of the door,
Shelves in the refrigerator provided in a plurality of the refrigerating chambers,
A light emitting diode provided in a plurality of rows in the front-rear direction on an upper surface of the refrigerating chamber,
The heat transfer of the light emitting diode is located in front of the front end of the shelf in the refrigerator,
The rear row of the light emitting diode is located above the shelf in the refrigerator and comprises a rear end of the shelf in the refrigerator at the uppermost end within the irradiation angle of the light emitting diode.

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