KR102217118B1 - Personal refrigerators having bottom machine rooms - Google Patents

Abstract

The present invention suggests a small refrigerator which can be conveniently used and is visually designed to have an aesthetic line. The small refrigerator of the present invention comprises: a refrigerator body (10) having a storage space (12) for storage; a front surface door (20) for opening or closing a front open surface of the refrigerator body; and an upper part door (30) for opening or closing the upper open surface of the refrigerator body. Moreover, a mechanical compartment casing (40) is assembled to the lower part of the refrigerator body, and parts such as a printed circuit board necessary for driving the refrigerator are embedded in the mechanical compartment casing. The thermoelectric element (50) is installed on the side surface of the refrigerator body, and the heat absorbing part of the thermoelectric element is installed to be exposed toward the storage space of the refrigerator body. According to the present invention, the mechanical compartment casing (40) has a partition wall (48) formed therein, wherein the partition wall has the same shape as that of the refrigerator body and comparts the inside of the mechanical compartment corresponding to the lower portion of the thermoelectric element.

Description

Small refrigerators having bottom machine rooms {Personal refrigerators having bottom machine rooms}

The present invention relates to a small refrigerator, and more particularly, to a small refrigerator for personal use, which can be opened and closed in various directions and has a machine room at a lower end while generating cool air using a thermoelectric element.

Refrigerators for storing foods and other stored objects at low temperatures have been developed in various forms since long ago. In recent years when the number of single people is increasing, it can be said that a lot of personal home appliances are developed and marketed in consideration of the living environment of such single people.

And it can be said that the current small refrigerator has a relatively small storage space and is used as an auxiliary refrigerator. In addition, small refrigerators for various purposes, such as a small refrigerator for cosmetics or a wine refrigerator having a small storage space, have been developed and marketed.

However, current small refrigerators only have a fixed form, that is, a hexahedral refrigerator, and moreover, because of their small capacity, they have only a certain form of use that allows storage to enter and exit through a single door installed in the front. There is a disadvantage of presenting only boring designs.

The present invention in consideration of these points is to propose a small refrigerator that can be used for various purposes with a new aesthetic design.

In addition, the present invention proposes a small refrigerator capable of providing a sense of unity in exterior design by arranging a machine room in which components for driving the refrigerator are built in the lower end of the body to have the same shape.

In addition, the present invention intends to propose a small refrigerator that can relatively easily apply character works, which are in the trend of the recent trend.

In addition, the present invention intends to propose a small refrigerator capable of sufficiently practically responding to the surrounding environment by having various opening and closing directions.

A small refrigerator of the present invention for achieving this purpose includes a refrigerator main body having a storage space for storage, a front door for opening and closing the open front of the refrigerator main body, and an upper door for opening and closing the open upper surface of the refrigerator main body. Are doing. In addition, a machine room casing is assembled under the refrigerator main body, and components such as a printed circuit board necessary for driving the refrigerator are embedded in the machine room casing. Further, a thermoelectric element is installed on the side of the refrigerator body, and the heat absorbing portion of the thermoelectric element is installed to be exposed toward the storage space of the refrigerator body. In the present invention, the machine room casing has the same shape as the refrigerator body, and a partition wall for compartmentalizing the inside of the machine room corresponding to the lower portion of the thermoelectric element is formed.

According to another embodiment of the present invention, the storage space of the refrigerator body is divided into two to correspond to the front door and the upper door, a ventilation hole through which cold air can pass is formed, and a split shelf that is detachably installed with respect to the refrigerator body is provided. It contains more.

And in the present invention, it is preferable that the upper door is formed in a hemispherical shape as a whole.

In addition, according to the present invention, it is preferable that a speaker is installed inside the machine room casing, and a sound-permeable hole is formed in the front surface of the machine room casing.

According to the present invention having the above configuration, it can be seen that the storage space of the refrigerator main body is basically configured to be opened and closed using an upper door or a front door. Therefore, convenience in use is expected that it is possible to open the refrigerator in a free direction according to the use environment.

In addition, according to the present invention, the machine room casing is installed on the bottom of the refrigerator main body, and it can be seen that the outer shape has the same outer shape as the refrigerator main body. Therefore, it can be seen that the machine room and the refrigerator body are implementing a refrigerator capable of providing an integrated aesthetic.

In addition, according to the present invention, it can be seen that the storage space of the refrigerator main body is divided into an upper door side and a front door side by a divided shelf. Therefore, it can be seen that the user can efficiently use the storage space of the refrigerator by attaching and detaching the split shelf.

Here, the upper door of the present invention is configured to be opened by using the elastic force of the spring member (torsion spring), so that convenience in use can be expected more. In addition, in the present invention, by using a thermoelectric element, it can be said that the design is most suitable for a small refrigerator.

Furthermore, according to the present invention, it can be said that the cool air generated while contacting one thermoelectric element is divided up and down to be supplied into the storage space, thereby achieving optimization of the cold air flow path. In addition, the dividing shelf of the present invention has a function of dividing the internal space of the refrigerator, and circulating air in the storage space by means of a plurality of molded ventilation holes.

1 is an exemplary perspective view of a refrigerator according to the present invention.
Figure 2 is an exemplary perspective view of the present invention refrigerator door in an open state.
3 is an exploded perspective view of the refrigerator according to the present invention.
Figure 4 is a partial cut-away perspective view of the refrigerator of the present invention.
5 is a rear perspective view of the refrigerator according to the present invention.

Hereinafter, the present invention will be described in more detail based on the embodiment shown in the drawings.

1 and 2, the refrigerator of the present invention includes a refrigerator body 10 having a predetermined storage space 12 therein, and a front door opening and closing the front of the refrigerator body 10. (20), and an upper door 30 that opens and closes the upper surface of the refrigerator main body 10. By such a pair of doors 20 and 30, the front of the refrigerator main body 10 of the present invention may be opened, or the upper surface of which the upper door 30 is installed may be opened. Means that.

In this way, when the front door 20 and the upper door 30 are installed together for one storage space 12, there may be a convenience in which the internal storage material can be inserted or taken out through any door. In addition, in the present invention, in order to efficiently divide the storage space 12 of the refrigerator main body 10, a dividing shelf 14 is installed.

The dividing shelf 14 of the present invention divides the storage space 12 into two, so that the upper door 30 is opened to put or take out the storage space, and the front door 20 is opened to put or take out the storage. It has a function of dividing it into a storage space underneath it. In the illustrated embodiment, the dividing shelf 14 has a flange portion 14a extending radially outward. It can be seen that the flange portion 14a is configured to be supported in a state that is caught by the locking jaw 16 inside the open upper end or the open upper end of the main body 10.

The dividing shelf 14 of the present invention divides the storage space 12 into two, thereby providing the convenience of access to the storage according to the opening and closing of the front door 20 and the convenience of accessing the storage according to the opening and closing of the upper door 30. You can see that you can. In addition, since the split shelf 14 is provided with a plurality of vent holes 14c, it is configured to circulate cold air throughout the storage space 12, which is a smooth flow of cold air within one storage space 12. It means that circulation is possible.

In addition, the division shelf 14 is provided with a handle 14b extending upward, for example, by providing a pair of handles 14b, it is possible to provide convenience of attachment and detachment. In the illustrated embodiment, the split shelf 14 is supported in a state in which the flange portion 14a is caught by the locking protrusion 16 inside the open upper end or the open upper end of the main body 10. However, it is natural that the dividing shelf 14 can have various detachable shapes within the range dividing the storage space 12, and for example, it is possible to implement a shelf installed in the middle of the storage space 12.

Next, the opening and closing structure of each of the doors 20 and 30 will be briefly described. As shown in FIG. 1, the front door 20 is supported in a hinged manner so that one side of the front (left side of the door in the illustrated embodiment) is rotatable with respect to the refrigerator body 10. It can be said to be substantially the same principle as the support structure of the door.

In addition, it can be seen from FIG. 2 that the upper door 30 of the present invention is opened and closed upward based on the hinge shaft 32 in the horizontal direction. In this way, the configuration for opening and closing the upper door 30 in the vertical direction, as shown in Figs. 3 and 5, the hinge shaft 32 arranged in the horizontal direction is the upper door 30 and the refrigerator body 10 It is installed between.

In the illustrated embodiment, the hinge shaft 32 includes an upper door extension portion 34 extending downward from a portion of the upper door 30, and a concave portion of the main body 10 so that the upper door extension portion 34 is accommodated. It is installed between parts. And in the illustrated embodiment, for convenience of assembly, the hinge shaft 32 provided on the side of the upper door 30 is provided by a pair of hinge shaft support blocks 16a and 16b that are assembled to the refrigerator body 10. You can see that it is supported.

Accordingly, it can be seen that the upper door 30 can be opened and closed in the vertical direction with respect to the refrigerator body 10 with the hinge axis 32 in the horizontal direction. And, as shown in FIG. 5, a pair of torsion springs 38 are interposed on the left and right sides of the hinge shaft 32. One end of the torsion spring 38 is supported by the main body 10 and the other end is supported by the upper door 30, so that the upper door 30 is always elastically supported in the open direction.

Here, it is preferable that the elastic restoring force of the torsion spring 38 is set to such an extent that food stored in the inner space 12 can be taken out by opening the upper door 30. That is, when the latch installed in the front of the upper door 30 is released, the torsion spring opens so that the upper door 30 can be taken out of the storage space 12 even if the upper door 30 is not lifted separately. 38) is set to increase the usability.

In addition, a structure for locking the upper door 30 with respect to the refrigerator body 10 is installed on the front portion of the upper door 30. Looking at such a locking structure based on FIG. 4, a locking lever 36 is installed in the front interior of the upper door 30 so as to be rotatable around an intermediate portion. The locking hook 36a formed on the lower end of the locking lever 36 can be caught by the locking protrusion 17 fixed to the inside of the refrigerator body 10.

The upper end of the locking lever 36 is elastically supported by a spring S so that the locking hook 36a is always fastened to the locking protrusion 17. Therefore, in the state where the locking hook 36a is caught on the locking protrusion 17, the spring S elastically pushes the locking lever 36 in a direction capable of maintaining such a fastened state, so if there is no external force, the upper door 30 ) Will not open.

In this fastened state, in order to open the upper door 30, the upper portion of the hinge shaft of the locking lever 36 must be pushed rearward. This is by pressing the corresponding part of the front cover of the upper door 30, the shaft or protrusion on the rear surface pushes the locking lever 36 backward to contract the spring, while the locking hook 36a at the lower end of the locking lever 36 By being released from the locking jaw, the upper door 30 is opened.

The design elements of the refrigerator main body 10 and the upper door 30 of the present invention will be described. It can be seen that the above-described upper door 30 has a hemispherical shape. In the present invention, the hemispherical shape is a shape obtained by cutting an exact spherical shape (spherical shape) in half and a similar spherical shape, for example, an ellipsoid whose shape cut by a plane passing through the center plane is an ellipse, or a similar hemispherical shape such as a half of an elliptical sphere. It is intended to be used as an inclusive meaning.

If the upper door 30 is molded in a hemispherical shape as described above, it is possible to have a considerably advantageous advantage in terms of design. That is, in traditional home appliances such as refrigerators, it can be said that the mechanical elements related to the refrigeration cycle that influence the function of the product have already reached the limit of development. Therefore, in the design of such a product, a design element that can evoke an aesthetic sense to the viewer can be said to be one of the most important design elements of a product.

And if the upper door 30 is designed in a hemispherical shape as in the present invention, it has a very convenient shape to apply a character that can be said to be in the general trend of all products recently. In recent years, in a wide range of industries, especially, various characters are applied to products purchased by end consumers, and these characters are known to be closely related to the desire to purchase products.

Since such a character is usually created mainly on the subject of an animal or human body part, it can be said that it is closest to the hemispherical shape described above when the character is implemented in three dimensions. For example, assuming that there is a character using the head of an animal, it can be said that a hemispherical shape is the most desirable for implementing such a character. Conversely, geometric shapes such as a rectangular parallelepiped or a triangular pyramid shape are inevitably very disadvantageous in realizing a character.

As described above, in the present invention, by designing the upper door 30 in a hemispherical shape, it can be said that it is the most desirable and can be easily implemented when applying a character. In addition, according to the present invention, it can be seen that the refrigerator body 10 has a cylindrical shape. This cylindrical body 10 can be said to be to match the upper door 30 and its appearance. That is, when the upper door 30 is designed in a hemispherical shape, the refrigerator body 10 is designed in a cylindrical shape to show a sense of unity in appearance with the upper door 30.

However, it is obvious that the refrigerator body 10 cannot be limited to such a cylindrical shape in the present invention. For example, by transforming the four corners of a hexahedron into a partial arc-shaped cross-section (cross-sectional view), it is possible to implement a cylindrical body in which all corners are designed in a circular or curved shape, and even in this case, it has an overall curved shape. As a result, it can be assumed that it is possible to provide a sense of unity in design with the hemispherical upper door 30.

Next, a configuration for generating and supplying cold air in the refrigerator of the present invention will be described. As described above, since the refrigerator of the present invention is designed to be compact to be used as a multipurpose personal refrigerator, it is not practically desirable to configure a refrigeration cycle including a compressor and a heat exchanger. Therefore, in the present invention, the basic idea is to use a thermoelectric element (Peltier) for heat exchange.

As shown in FIG. 3, a thermoelectric element 50 is installed as a component for heat exchange in an intermediate portion of the refrigerator body 10. The thermoelectric element 50 is installed so that the heat absorbing portion 52 is exposed to the storage space 12 of the refrigerator body 10, and the heat generating portion faces the outside of the refrigerator. As can be seen with reference to FIG. 4, a duct cover 62 is installed on the inner part of the thermoelectric element 50.

In addition, a return portion 66 through which air can enter the thermoelectric element 50 is formed in the middle portion of the duct cover 62 having a shape extending in the vertical direction, and the air sucked through the return portion 66 Is cooled by heat exchange with the heat absorbing portion 53 of the thermoelectric element 50. The generated cold air is discharged from the upper and lower portions of the storage space 12 through a pair of outlet portions 62 and 64 respectively formed at the upper and lower ends of the duct cover 62. And such a flow of air is formed by a circulation fan (not shown) installed outside the duct cover 60.

A thermoelectric element casing 58 is installed on the outer surface of the refrigerator body 10 in which the thermoelectric element 50 is installed. A cooling fan 56 for cooling the heat generating portion of the thermoelectric element 50 is installed inside the thermoelectric element casing 58. The operation of the cooling fan 56 is to cool the heating part of the thermoelectric element 50, and a plurality of ventilation holes are formed in the thermoelectric element casing 58 to form an air flow for such cooling.

Here, the outlet 64 of the upper part of the duct cover 62 is installed on the upper part of the split shelf 14 and the lower part of the duct cover 62 is installed under the storage space 12. Therefore, looking at the overall circulation of air, the air that has been relatively hot due to heat exchange with the storage material inside the storage space 12 due to the operation of the circulation fan is a return part 66 formed in the middle of the duct cover 60 ) Through the thermoelectric element 50 side.

In addition, the air sucked into the thermoelectric element 50 through the return portion 66 is generated as cold air by heat exchange with the heat absorbing portion 52, and thereafter, outlet portions 62 respectively installed on the top and bottom of the duct cover 62 It is discharged into the storage space 12 through 64. In addition, the cold air discharged in this way is heat-exchanged with the stored material in the storage space 12, thereby increasing the temperature by itself while maintaining the stored material in a low temperature state, and the above-described process of re-entering the return portion 66 is repeated.

According to the present invention, as shown in FIG. 1, a mechanical seal casing 40 is installed under the refrigerator main body 10, and both are coupled using, for example, a plurality of screws. In addition, the machine room casing 40 of the present invention has the same shape as the refrigerator main body 10, and thus has an overall integrated appearance. In addition, a controller required for driving and controlling the refrigerator is built into the machine room casing 40.

As shown in Fig. 3, a PCB cover 42 for protecting a PCB substrate to be embedded is installed inside the machine room casing 40. A printed circuit board for overall control of the refrigerator is built into the PCB cover 42. It is preferable that the PCB cover 42 for protecting such a printed circuit board is formed of a flame-retardant material to protect the internal components from flames.

In addition, a control panel 44 is installed on the front of the machine room casing 40. The control panel 44 has a function of receiving an input signal for controlling the refrigerator and notifying a user of the current state of the refrigerator through a display. In addition, the control panel 44 is designed to receive a control signal for controlling a Bluetooth speaker (not shown) built into the machine room casing 40.

Here, a speaker (not shown) having a Bluetooth function is installed inside the machine room casing 40, and a plurality of sound-through holes 46 are formed in the front of the speaker so as to transmit sound from the speaker to the outside. In addition, a partition wall 48 is installed inside the machine room casing 40 of the present invention, and the partition wall 48 is intended to substantially prevent damage to electrical components (PCB substrates, etc.) caused by water.

As mentioned above, a thermoelectric element 50 (Peltier) is used for heat exchange in the refrigerator of the present invention. The thermoelectric element 50 has a heat generating portion and a heat absorbing portion, and water droplets may form due to a temperature difference with the outside air. When water droplets that may be generated in the thermoelectric element 50 fall downward, electrical components inside the machine room casing 40 are damaged. Therefore, a partition wall 48 is installed to isolate a part of the machine room corresponding to the lower part of the thermoelectric element 50 from other parts of the machine room.

In addition, a shelf 19 (refer to FIG. 3) may be installed for efficient storage of storage in the storage space 12 of the refrigerator main body 10, and a door basket 18 is provided inside the front door 10. It is natural that it can be installed. As described above, the present invention can be seen that the subject of the present invention is a small refrigerator having a configuration that facilitates the smooth and natural flow of cold air and the most convenient character implementation, and a configuration that allows access to stored objects while using a thermoelectric element. .

Next, based on the above-described embodiment, another embodiment that can be modified will be described.

As described above, the structure of the refrigerator main body 10 may be formed to have a cylindrical shape with rounded corners in addition to the cylindrical shape as described above. And in the illustrated embodiment, the upper door 30 is configured to open and close the entire hemispherical shape, but it can be seen that it is sufficient to open and close at least a part of the upper door 30 made in the hemispherical shape. have.

In the illustrated embodiment, while the entire upper door 30 is opened and closed, the entire upper door 30 is formed in a hemispherical shape. However, although the entire upper door 30 is formed in a hemispherical shape, it will be possible to configure only a part of the upper door 30 to be opened and closed. And even in this case, it is natural that the entire upper door having a hemispherical shape will be suitable for implementing a character.

In addition, in the illustrated embodiment, the dividing shelf 14 is designed in a detachable shape that is separated upwards, but the installation position is not limited as long as the storage space 12 of the refrigerator main body can be divided into two. In addition, the thermoelectric element for cooling the storage space of the refrigerator according to the present invention may be variously modified within a range in which it is installed to have a heat absorbing portion exposed toward the storage space of the refrigerator.

10 ..... refrigerator body
12 ..... storage space
14 ..... Split shelf
16 ..... stumbling
20 ..... Front door
30 ..... upper door
40 ..... Machine thread casing
50 ..... Thermoelectric device
52 ..... Heat absorbing part of thermoelectric element
56 ..... cooling fan
58 ..... Thermoelectric element casing

Claims (4)

A refrigerator body having a storage space for storage;
A front door for opening and closing the opened front of the refrigerator body;
An upper door that is supported to be opened and closed by a hinge shaft installed in a horizontal direction to open an open upper surface of the refrigerator body to the upper surface, and is formed in a hemispherical shape as a whole;
The storage space of the refrigerator main body is divided into two to correspond to the front door and the upper door, and a ventilation hole through which cold air can pass is formed, and the flange portion is supported by the locking jaw inside the open upper part or the open upper part. Detachable split shelf;
A thermoelectric element installed in a middle portion of the refrigerator body and having a heat absorbing portion exposed toward the storage space; And
The return part is installed inside the thermoelectric element and formed in the center so that the air inside the storage space can enter the thermoelectric element, and the cold air generated by heat exchange with the heat absorbing part of the thermoelectric element coming in through the return part and the storage space It is composed of a duct cover each having an upper end portion and a lower end portion to be discharged;
The cold air coming out through the outlet at the upper end of the duct cover is supplied to the storage space above the split shelf through a number of ventilation holes of the split shelf, and the cold air coming out through the outlet at the lower end of the duct cover is supplied to the storage space below the split shelf. ;
The machine room casing has the same shape as the refrigerator body, and a partition wall for compartmentalizing the inside of the machine room corresponding to the lower part of the thermoelectric element is formed.



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