RU2422737C1 - Refrigerator - Google Patents

Abstract

FIELD: personal use articles.

SUBSTANCE: refrigerator contains a body including a refrigeration chamber having a rear wall, a chiller and a force-draught blower. The blower delivers cold air as generated by the chiller into the refrigeration chamber through the inlet channel. The force-draught blower is positioned upstream the air flow as compared to the chiller and under the latter. Under the chiller but over the force-draught blower a water catch is located that collects melted water discharged from the chiller.

EFFECT: design of a refrigerator with a simplified configuration of the outlet channel and high refrigeration efficiency due to energy loss reduction.

8 cl, 9 dwg

Description

The present invention relates to a refrigerator comprising a main body including a refrigerator with a rear wall, a cooler, and a blower that delivers cool air generated by the cooler to the refrigerator through an exhaust duct.

One example of a domestic refrigerator is disclosed in Japanese patent JP 3594545, hereinafter referred to as the first related example. As can be seen in FIGS. 5A and 5B, the refrigerator comprises a cabinet 1 divided into a refrigerator 2, a vegetable compartment 3 and a freezer, listed in the sequence of their location inside the cabinet 1 from top to bottom, and a pair of coolers, one of which is located in the refrigerator chamber 2, and the other is located in the freezer 4. On the upper part of the rear wall of the refrigeration chamber 2, there is a cooler chamber 7, which contains a cooler 5. Above the cooler chamber 7, in other words, in the uppermost part of the refrigeration chamber 2 agnetatelny fan 8 for circulating the cold air inside the refrigerator compartment 2 and the vegetable compartment 3.

On the rear wall of the housing 1 there is a suction channel 9, also called an inlet channel, which comprises a lower end surrounded by a vegetable chamber 3 and which extends upward towards the cooler chamber 7. In addition, a channel 10 for supplying cold air is formed, which branches to the left and right close to the blower fan 8 for passing down the left and right parts of the cooler chamber 7 and the suction channel 9. The channel 10 for supplying cold air contains a plurality of exhaust openings 10a formed in the refrigerator compartment 2 and the compartment 3 for vegetables. On the upper wall of the cooling chamber 2, a channel 11 is located on the upper surface, which extends forward from the part containing the blower fan 8.

As shown by the solid arrows and dashed arrows in FIGS. 5A and 5B, the actuation of the fan causes the air inside the vegetable chamber 3 to be sucked from the suction channel 9. Then, the intake air is cooled in the cooler 5 inside the cooler chamber 7 and then passes through the discharge fan 8 for supplying to the channel 10 for supplying cold air and channel 11 on the upper surface. Cold air is supplied to the refrigerating chamber 2 from the outlet 11a of the front end of the channel 11 on the upper surface, and also is supplied to the refrigerating chamber 2 and the vegetable chamber 3 through a plurality of outlet openings 11a of the channel 10 for supplying coolant air to the cooler.

Another type of refrigerator, which differs from the first related example by the location of the cooler and the blower fan, hereinafter referred to as the second related example, is disclosed in Japanese publication JP 2001-27469 A. The open refrigerator, as shown in FIGS. 6A and 6B, comprises a cooler chamber 12, containing a cooler 5 located on the rear wall of the refrigerating chamber 2, and a channel 13 for supplying cold air, passing upward from the chamber 12 of the cooler. In front of the cooler chamber 12, a blower fan housing 14 is located, comprising a blower fan 15, which is connected to the cooler chamber 12 at its lower end. The actuation of the blower fan 15 causes air from the cooler chamber 12 to be sucked into the blower case 14. The intake air is cooled as it passes through the cooler 5 inside the cooler chamber 12 for supplying to the refrigerating chamber 2 through the channel 13 for supplying cold air. The above air circulation is repeated.

However, the above configurations have the following disadvantages. In the first related example shown in FIGS. 5A and 5B, the blower fan 8 is installed in a very limited space in the uppermost part of the rear wall of the refrigeration chamber 2. The limitation of the space additionally requires folding back the cooling channel connecting to the suction channel 9, the cooler chamber 7 and channel 10 for supplying cold air, and thus it is not possible to obtain sufficient air flow.

One solution to getting enough airflow is to increase the overall channel size. However, with increasing channel size, less free space or volume remains in the refrigerator, which means that its storage volume for food is reduced. The blower fan 8 is located downstream of the cooler 5. Since the blower fan motor 8 generates heat, the air once cooled by the cooler 5 is reheated as it passes through the blower fan 8, which leads to energy loss.

In addition, in the second related example shown in FIG. 6, the cooler chamber 12 and the blower fan housing 14 are located behind the rear wall for positioning one above the other in the forward and backward directions. This arrangement increases the thickness of the rear wall of the refrigerator compartment 2, which protrudes forward and, thus, reduces the depth of the refrigerator compartment 2 to sizes that cause the user a dull feeling when opening the refrigerator door and when he looks inside the refrigerator compartment 2.

One objective of the present invention is to provide a refrigerator comprising a cooler, a blower fan and an exhaust channel on the rear wall of the refrigerator, with a simplified channel configuration and high cooling efficiency and, in addition, a sufficiently provided volume in the chambers, so that the user does not experience an oppressive feeling.

In one aspect of the present invention, there is provided a refrigerator comprising a housing including a refrigerator with a rear wall, a cooler and a blower that delivers cold air generated by the cooler into the refrigerator through an exhaust duct in which the blower is located upstream relative to and under the cooler.

According to the above configuration, the air flow generated by driving the blower fan passes through a cooler to produce cold air, after which cold air is supplied to the cooler chamber through an exhaust duct. Since the exhaust channel can be located above the cooler, the exhaust channel can be made in direct form without bending. The above configuration provides sufficient airflow. Since heat emitting elements need not be located downstream of the cooler, energy loss can be prevented. In addition, since the discharge fan is located under the cooler, they take up less space, especially in the forward and backward directions, compared to the arrangement in which the cooler and the discharge fan are arranged one after the other, thereby reducing the amount of forward protrusion of the rear wall inside the refrigerator.

The invention will now be described in more detail with reference to the accompanying drawings, in which:

figure 1 is a side view on the right in a vertical cross section of the refrigerator in accordance with one embodiment of the present disclosure;

figure 2 is a front view of the refrigerator, depicted with the remote doors of each chamber;

figure 3 is a side view in vertical transverse section of a part including a refrigerating chamber and a chamber for vegetables;

figa is a perspective view of the inner lower part of the refrigerator;

figv is a perspective view of a chamber for vegetables with a removed partition;

5A is a front view of a refrigerator case of a first related example;

figv is a side view on the right in a vertical cross section of the refrigerator body of the first related example;

figa is a front view of the main parts of the refrigeration chamber of the second related example; and

figv is a side view on the right in a vertical cross section of part of the rear wall of the second related example.

One embodiment of the present invention will be described with reference to FIGS. 1-4B.

Figures 1 and 2 depict a general configuration of a refrigerator body 21 in accordance with the present embodiment. The housing 21 is made in the form of an elongated rectangular heat-resistant box 22 having an open front surface. The housing 21 comprises, from top to bottom, in the listed order, a refrigeration chamber 23, a vegetable compartment 24 and a freezer 25. The refrigeration compartment 23 and the vegetable compartment 24 are separated by a partition 26 located between them, as shown in FIGS. 3 and 4A, so that the refrigeration compartment 23 is located above the camera 24 for vegetables.

Similarly, the vegetable compartment 24 and the freezer 25 are separated by a heat-resistant partition 27, so that the vegetable compartment 24 is located above the freezer 25. Although not shown, not described in detail, the freezer 25 is further divided into upper and lower compartments, and an upper compartment divided into left and right branches. The left compartment is used as a chamber for ice cubes containing an automatic ice maker. The front side of the refrigerator compartment 23 is closed by a heat-resistant door 23a, which is pivotally connected to ensure its opening and closing. The vegetable compartment 24 is closed by a heat-resistant door 24a having a drawer configuration. A container 28 is attached to the rear side of the heat-resistant door 24a, as shown in FIGS. 3, 4A and 4B. The front surfaces of the compartments or chambers of the freezer 25 are also closed by a heat-resistant door 25a having a drawer configuration that includes a container 25b connected to its rear side.

In addition, the inside of the refrigerator compartment 23 is vertically divided into compartments by shelves 29. In the lowermost compartment, located above the partition 26, there is a cooler 30. As shown in figures 1 and 3, the cooler 30 contains a drawer-type container or cooler case to move back and forth to and from cooler 30. A lamp 48 is mounted on the ceiling of the refrigerator compartment 23 to illuminate the interior of the compartment. In the refrigerator compartment 23, a temperature limit of approximately 2 ° C is set, while in the cooler 30 a temperature limit of approximately 0 ° C is set. In addition, a temperature limit of approximately 4 ° C is set in the vegetable compartment 24, while a temperature limit of approximately -18 ° C is set in the freezer compartment 25.

Although not fully shown in detail, the housing 21 comprises a pair of coolers providing a cooling cycle. The pair of coolers comprises an evaporator 32 for cooling the refrigerating chamber 23 and a chamber 24 for vegetables and a cooler 33 of the freezing chamber for cooling the freezing chamber 25. The evaporator 32 and the cooler 33 are made with a relatively large width to provide a large surface area for absorbing heat, in other words, to provide high cooling performance.

As shown in FIG. 1, an engine room 34 is located at the lower end of the rear side of the housing 21, which contains elements not shown in detail, such as a compressor 49 and a condenser, which provide a cooling cycle. The engine room 34 further comprises elements such as a cooling fan for cooling the compressor 49 and the condenser and a melt water evaporator. In the lower part of the rear side of the housing 21 is a control panel 50 on which a microcomputer or the like is installed for centralized control of the refrigerator.

As shown in figures 1 and 2, on the back wall of the freezer 25 inside the housing 21 is a cooler chamber 35 for holding the freezer 25, which contains elements such as a cooler 33 for the freezer and a defrosting heating device (not shown) in its lower part parts, while in the upper part there is a blower fan 36 of the freezer. A cold air outlet 35a is located in the front middle part of the freezer cooler chamber 35, and a return hole 35b is located at the front lower end.

In accordance with the above configuration, when the blower fan 36 of the freezer is driven, cold air generated by the cooler 33 is supplied to the freezer 25 from the cold air outlet 35a. Then, cold air in the freezer 25 is circulated back to the freezer cooler chamber 35 through the return opening 35b. In the lower part of the cooler 33 of the refrigeration chamber inside the chamber 35 of the cooler of the freezer, there is a water intake 37 for collecting melt water exiting the cooler 33 of the freezer. Melt water collected by the water intake 37 is sent to the melt water evaporator inside the engine room 34 for evaporation.

An evaporator 32 is located on the rear wall of the housing 21. In addition, elements such as an exhaust channel 38 for supplying cold air generated by the evaporator 32 to the cooling chamber 23 and a discharge fan 39 for circulating cold air are arranged as follows. As can be seen in figures 1-3, on the rear wall of the housing 21, the cooler chamber 40, containing the evaporator 32, is located behind the cooler chamber 30, located in the lowermost compartment of the refrigeration chamber 23.

The front wall 40a of the cooler chamber 40, in other words, the rear wall of the cooler chamber 30 is heat resistant. On the rear wall of the cooling chamber 23, the exhaust channel 38 extends upward with a constant width. The upper end of the cooler chamber 40 is connected to the lower end of the outlet channel 38. As shown in FIGS. 2 and 3, the outlet channel 38 comprises a plurality of outlet openings 38a that are open to the refrigerator chamber 33.

In addition, as can be seen in FIGS. 1 and 3, in the lower part of the cooler chamber 40, the water inlet 41 is located under the evaporator 32 for receiving melt water leaving the evaporator 32. The water collected by the water inlet 41 is directed to the melt water evaporator inside the engine room 34 for evaporation.

Then, as can be seen, for example, in FIG. 3, the discharge fan 36 is located behind the vegetable chamber 24, as well as the air flow channel 42 and the inlet channel 43. The air flow channel 42 is located behind the vegetable chamber 24 and extends in the direction up and down with a width essentially equal to the width of the exhaust channel 38. The upper end of the channel 42 for air flow bypasses the intake 41 to connect with the front side of the lower end of the chamber 40 of the cooler.

On the front side of the lower end of the air flow channel 42, the widened end of the hole 44 is located in the center of the side channel. The blower fan 39 is positioned so that the blades for creating air flow are located inside the widened end 44 of the hole. The blower fan 39 draws in air from the front side and discharges air toward the outside, in this case, upward. The blower fan 39 is located a little further relative to the evaporator 32. Thus, the channel 42 for air flow, when viewed from the side, extends almost vertically and slightly bent at its upper end to connect to the front side of the lower end of the cooler chamber 40.

In addition, as shown in FIG. 3, on the front surface side of the air flow passage 42, the inlet channel 43 is arranged to overlap with the air flow passage 42 as viewed from the front. The inlet channel 43 is made with a width substantially equal to the width of the outlet channel 38 and extends slightly below the discharge fan 39 from the ceiling of the vegetable chamber 24. The upper end of the inlet 43 is connected to a laterally elongated inlet 45 formed on the rear side of the lower portion of the refrigeration chamber 23 or the cooler chamber 30. In addition, as shown in FIG. 3, a hole 43a is formed in the lower part of the inlet channel 43.

As shown in FIGS. 3, 4A and 4B, a channel 46 for supplying cold air is located on the partition 26 that separates the refrigerating chamber 23 and the vegetable chamber 24. Channel 46 for supplying cold air directs part of the cold air from the refrigerating chamber 23 to the chamber 24 for vegetables. As shown in figv, the channel 46 for supplying cold air is located on the right half of the partition 26 for passage in the forward and reverse directions. As further shown in FIG. 3, the cold air supply channel 46 comprises a front supply opening 46a at its front end and a rear supply opening 46b formed at its rear end. The rear right end of the cold air supply duct 46 is connected to the refrigerating chamber 23 by a connecting part 47 located on the right side of the inlet 45. Thus, a part of the cold air inside the refrigerating chamber 23 is supplied to the front of the vegetable compartment 24 where the bottles are stored with drinks, or in the back of the vegetable compartment 24.

In accordance with the above configuration, when the blower fan 39 is driven, air from the refrigeration chamber 23 is sucked through the suction inlet 45 into the inlet 43, as shown by the black line in FIG. 3. In this case, air from the vegetable chamber 24 is sucked into the inlet channel 43 through the opening 43a to direct air into the cooler chamber 40 through the air flow channel 42. As shown by the white volumetric arrow, cold air is generated by the evaporator 32, and the generated cold air is supplied to the cooling chamber 23 from each outlet 38a of the outlet channel 38.

The cold air supplied to the refrigerating chamber 23 after it has cooled its contents, which is most likely a food product, is sucked into the inlet channel 43 through the inlet 45. In addition, part of the cold air from the refrigerating chamber 23 passes through the channel 46 for supplying cold air through the connecting part 47 for supplying to the chamber 24 for vegetables. The cold air supplied to the vegetable chamber 4 after cooling its contents, which is most likely vegetables, is sucked into the inlet channel 43 through the opening 43a. The above-described circulation of cold air is then repeated.

The blower fan 39 is located downstream of the evaporator 32 and below the evaporator 32. In addition, the blower fan 39 is located below the inlet 41 and slightly further relative to the evaporator 32.

The peripheral structures of the evaporator 32 described above in accordance with the present embodiment provide the following operation and effect. An exhaust duct 38 supplying cold air to a portion of the rear side of the refrigerating chamber 23 is made in a simple form extending straight upward with a constant width from the cooler chamber 40, which contains the evaporator 32. Thus, unlike the first related example shown in FIG. .5A and 5B, which requires that the channel for cold air flow be bent vertically backwards, sufficient air flow can be obtained.

In addition, the distance between the evaporator 32 and each of the outlet openings 38a of the outlet channel 38 can be made relatively short. In addition, a heat emitting element, such as an electric blower motor, is located downstream of the evaporator 32. Thus, cold air, which has a sufficiently low temperature, can be supplied to the cooling chamber 23 from each outlet 38a of the outlet 38 to increase cooling efficiency.

A blower fan 36 containing heat emitting elements, such as an electric motor, is mounted upstream of the evaporator 32 and behind the vegetable compartment 24, which has a relatively higher temperature than the refrigeration chamber 23 and the cooler chamber 30. In addition, the evaporator 32 having the lowest temperature is located behind the cooler chamber 30, which has a relatively low temperature compared to the refrigeration chamber 23 and the vegetable chamber 24. Thus, each of the elements of the refrigerator can be located in the corresponding position, taking into account the temperature distribution of the refrigerating chamber 23, the cooler chamber 30 and the vegetable chamber 24. As a result, cooling efficiency that satisfies the conditions of each chamber can be obtained, and the thermal insulation design is also simplified.

Furthermore, coolers or pressure fans are not located on the surface of the rear side of the refrigeration chamber 23, with the exception of the cooler chamber 30, thus only a relatively thin outlet channel 38 is located. The above configuration increases the depth in the forward and backward directions of the inside of the refrigeration chamber 23 to provide more volume for food storage. In addition, the capacity provided by the increased storage volume is less stressful for the user compared to the oppressive atmosphere of a related example.

The presence of the cooler chamber 40 causes the rear surface of the cooler chamber 30 to protrude forward. However, the cooler chamber and the blower fan are not located one after the other. Thus, the front wall 40a, made of heat-resistant material, can be made relatively thin, and also the forward projection of this part can be made relatively smaller.

Similarly, the surface of the rear side of the vegetable chamber 24 contains elements such as a blower fan 39, and thus protrudes forward, however, the protrusion is relatively smaller compared to the position of the cooler chamber and the blower fan one after the other. The cooler chamber 30 and the vegetable chamber 24 are made in the form of a drawer for holding containers 31 and 28 in the respective compartments and removing them. Thus, there is very little likelihood of a protrusion of the rear wall exposed to the user, and thus eliminates the oppressive atmosphere experienced by the user.

In addition, in accordance with the present embodiment, the inlet channel 43 and the air flow channel 42 are arranged one after another on the rear wall of the vegetable chamber 24. Thus, a heat-resistant wall is not required, which means that the inside of the inlet 43 can serve as a heat-resistant space. To clarify, when, for example, the blower fan 39 stops working, the cold air generated by the evaporator 32 contained in the cooler chamber 40 may be lowered into the air flow channel 42, however, the inlet channel 43 will provide some degree of isolation in such cases. As a result, an excessive drop in temperature inside the vegetable compartment 24 can be prevented while dew condensation is prevented on the front surface of the inlet channel 43 and the rear surface of the vegetable compartment 24.

According to the above configuration, the air flow passage 42 must bypass the water inlet 41, which collects melt water exiting the evaporator 32. Since the blower fan 39 is located forward relative to the cooling chamber 23 in the present embodiment, the bending of the air flow passage 42 can be reduced, but not much reduced. Thus, uniform airflow is provided between the blower fan 39 and the cooler chamber 40. As you can easily understand, the presence of a water intake 41 prevents melt water or dew from leaving the refrigeration chamber 23 to drain onto elements such as a blower fan 39.

In the above described embodiment, the present invention was illustrated with a refrigerator containing a pair of coolers, that is, an evaporator 32 and a cooler 33 of a freezer. However, the present invention can be illustrated with a configuration in which a single cooler is located in the housing 21, and the cold air flow is regulated in each chamber using devices such as dampers. The present invention is not limited to the above-described embodiment, and may include various modifications to the configuration or arrangement of each chamber within the housing, the arrangement of components such as coolers and channel configurations, but is not limited to the foregoing.

The foregoing description and drawings illustrate only the principles of the present disclosure and are not construed in a narrow sense. Various changes and modifications will become apparent to those skilled in the art. It can be seen that all such changes and modifications are included in the scope of the disclosure, as defined in the attached claims.

Claims (8)

1. A refrigerator comprising a housing including a refrigerating chamber having a rear wall, a cooler and a blower fan that delivers cold air generated by the cooler to the refrigeration chamber through an exhaust duct, wherein the blowing fan is located upstream of the cooler and under the cooler, and under the cooler, but above the discharge fan, there is a water intake that collects the melt water leaving the cooler. 2. The refrigerator according to claim 1, in which the discharge fan is located in front of the cooler. 3. The refrigerator according to claim 2, in which the refrigerating chamber is located in the upper part of the refrigerator body, wherein the refrigerating chamber includes a cooler chamber in its lowermost compartment, and the vegetable compartment is located under the refrigerating chamber, and in which the cooler is located behind the cooler chamber and the blower fan is located behind the vegetable chamber. 4. The refrigerator according to claim 3, in which both the cooler chamber and the vegetable chamber are provided with a container in the form of a drawer. 5. The refrigerator according to claim 1, in which the refrigerating chamber is located in the upper part of the refrigerator body, wherein the refrigerating chamber includes a cooler chamber in its lowermost compartment, and the vegetable chamber is located under the refrigerating chamber, wherein the cooler is located behind the cooler chamber, and a blower fan is located behind the vegetable compartment. 6. The refrigerator according to claim 5, in which both the cooler chamber and the vegetable chamber are provided with a container in the form of a drawer. 7. The refrigerator according to one of claims 3 to 6, in which the rear wall of the vegetable chamber contains an inlet channel for supplying cold air to the part containing the discharge fan from the bottom of the cooler chamber and an air flow channel that directs the air flow from the discharge fan in the part containing the cooler, while the inlet channel and the channel for air flow are located one behind the other. 8. The refrigerator according to claim 7, in which the inlet channel passes further under the discharge fan and has an opening in its lower part.

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