The present disclosure relates generally to refrigeration systems and, more particularly (although not necessarily exclusively), to an airflow system for controlling temperature in integrated compartments in a refrigeration appliance.
Refrigeration systems can include an evaporator and a compressor. The compressor can pump refrigerant through the refrigeration system. For example, a signal from a sensor can indicate that a temperature of the refrigeration system is above a set temperature. In response, the compressor can turn on to pump the refrigerant to facilitate cooling of the refrigeration system. Additionally, the refrigerant pumped by the compressor can pass through the evaporator to cool a surface of the evaporator. Thus, the evaporator can facilitate cooling of air within the refrigeration system. In some examples, the refrigeration system can include one or more compartments and the air cooled by the evaporator can be distributed to the one or more compartments to cool the one or more compartments. A user may set temperatures of the one or more compartments and the evaporator, compressor, and other suitable components can be used to generate the temperatures. Different temperatures for different compartments can be desirable to optimize preservation of fruits, vegetables, or other perishables.
It is accordingly an object of the invention to provide an airflow system for temperature control in integrated compartments in a refrigeration appliance that overcome the above-mentioned disadvantages of the prior art devices and methods of this general type.
With the foregoing and other objects in view there is provided, in accordance with the invention, an airflow system. The airflow system contains an evaporator for positioning in a first compartment of a refrigeration appliance, the evaporator being configured to decrease a temperature of air in the first compartment. A first supply duct is configured for coupling to the first compartment and a second compartment, and is configured to direct a first air flow from the first compartment to the second compartment. A damper having a flap is provided, and the flap is configured to be positioned based on a temperature setting of the second compartment. A second supply duct is configured for coupling to the first compartment and a third compartment and is configured to direct a second air flow from the first compartment to the third compartment. A first return duct is configured for coupling to the first compartment and the second compartment and is configured to direct a third air flow from the second compartment to the evaporator. A second return duct is configured for coupling to the first compartment and the third compartment and configured to direct a fourth air flow from the third compartment to the evaporator.
In accordance with an added feature of the invention, there is further provided a housing having a first geometry extending into a first opening of the first supply duct, wherein the housing is configured to receive air. A fan is provided and configured for positioning in the housing and to distribute the first air flow through the first geometry to the damper positioned in the first opening of the first supply duct. The flap is configured for being in an open position or a closed position, wherein the open position corresponds to the damper directing the first air flow to the second compartment via the first supply duct, and the closed position corresponds to the damper obstructing the first supply duct.
In accordance with an additional features of the invention, a mainboard is configured to provide a plurality of temperature settings for the second compartment, wherein the mainboard is configured to receive a setting of a plurality of temperature settings from a user. The temperature settings include temperatures ranging from −18 degrees celsius to 4 degrees celsius.
In accordance with a further feature of the invention, a sensor is communicatively coupled to a fan and the damper. The sensor is configured to measure a first temperature of the second compartment, and the setting is a second temperature of the second compartment. The mainboard is configured to provide an indication of a speed of the fan and a position of the flap based on a difference between the first temperature and the second temperature.
In accordance with another feature of the invention, at least one inner liner panel is provided. The first supply duct, the second supply duct, the first return duct, and the second return duct are configured to be fastened to the at least one inner liner panel. The at least one inner liner panel is configured to be positioned on a first backside of the first compartment, a second backside of the second compartment, and a third backside of the third compartment.
In accordance with a further added feature of the invention, foam is provided and configured for positioning proximate to the first supply duct, the second supply duct, the first return duct, and the second return duct. The foam is further configured to be positioned between the at least one inner liner panel and the outer liner panel.
In accordance with yet another feature of the invention, the first supply duct, the second supply duct, the first return duct, and the second return duct further contain a plurality of reinforcement components.
With the foregoing and other objects in view there is provided, in accordance with the invention, a method containing the steps of: providing a first air flow that is cooled by an evaporator positioned in a first compartment of a refrigeration appliance, and controlling, via an airflow system, a temperature of a second compartment by the further substeps of: receiving, via a mainboard, a temperature setting for the second compartment; receiving, via the mainboard, a measured temperature detected by a sensor of the second compartment; controlling, by the mainboard, a flap of a damper positioned in a first supply duct based on a difference between the temperature setting and the measured temperature; directing, by the first supply duct coupled to the first compartment and the second compartment, the first air flow from the first compartment to the second compartment; and directing, by a first return duct coupled to the first compartment and the second compartment, a second air flow from the second compartment to the evaporator.
Other features which are considered as characteristic for the invention are set forth in the appended claims.
Although the invention is illustrated and described herein as embodied in an airflow system for temperature control in integrated compartments in a refrigeration appliance, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims.
The construction and method of operation of the invention, however, together with additional objects and advantages thereof will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings.
Certain aspects and examples of the present disclosure relate to an airflow system for temperature control in a refrigeration appliance. The airflow system may be included in a refrigeration appliance such as a refrigerator, freezer, or other suitable refrigeration appliance. The refrigeration appliance may include one or more compartments in a body of the refrigeration appliance for storing food or other perishables. Additionally, the refrigeration appliance can include an evaporator that can have a cool surface for cooling air within the refrigeration appliance. The airflow system can include a fan and a damper for distributing and controlling airflow in the refrigeration appliance. By distributing and controlling the airflow in the refrigeration appliance, the airflow system can control the temperature of the refrigeration appliance, the compartments of the refrigeration appliance, or a combination thereof. Additionally, the airflow system can distribute air evenly to provide a uniform temperature throughout a full volume of the one or more compartments, the body of the refrigeration appliance, or a combination thereof.
Conventional refrigeration systems may not generate sufficient airflow or adequately control the airflow to cause significant changes in temperature to compartments in a refrigeration appliance. Additionally, conventional refrigeration systems may involve additional energy resources, fans, evaporators, etc. to effectively control airflow between compartments. Embodiments of the present disclosure provide a system with at least one supply duct and at least one return duct that can generate an efficient cycle of airflow between compartments in a refrigeration appliance. Therefore, the system can decrease the energy consumption and the noise level associated with cooling the refrigeration appliance. Additionally, the system can include different numbers of supply ducts and return ducts, different sizes of supply ducts and return ducts, or other suitable changes to supply duct and return duct configurations to provide a flexible airflow system that can be applied to refrigeration appliances of varying size, complexity, features, etc.
Additionally, different temperatures can be desirable for compartments of the refrigeration appliance, or temperatures of the compartments can change at different rates. For example, a user may change a temperature setting of a compartment from a first temperature associated with a refrigeration compartment to a second temperature associated with a freezer compartment. Therefore, the airflow system may direct airflow, create stronger airflow, or a combination thereof to provide a change in temperature from the first temperature to the second temperature in the compartment. Additionally, the compartments can include sensors for measuring temperatures of the compartments. Therefore, the airflow system may selectively direct airflow, block airflow, or create stronger airflow to the compartments of the refrigeration appliance via supply ducts and return ducts based on differences between measured temperatures of the compartments and set temperatures of the compartments.
In a particular example, a refrigeration appliance can include a freezer compartment, an icemaker compartment, and a flex compartment that can change between freezer temperatures and refrigeration temperatures. The airflow system can include a first fan positioned in a first housing for distributing first air. Additionally, a second fan can be positioned in a second housing for distributing second air. The first housing and second housing can be positioned in the freezer compartment proximate to an evaporator. The airflow system can include a first supply duct that can connect to the freezer compartment and the flex compartment. The airflow system can also include a second supply duct that can connect to the freezer compartment and the icemaker compartment. The first supply duct can direct a first air stream to the flex compartment. The second supply duct can direct a second air stream to the icemaker compartment. A damper with a flap can be positioned in the first supply duct. A position of the flap can be adjusted to control airflow to the flex compartment based on a temperature setting of the flex compartment. The airflow system can include a first return duct that can connect to the freezer compartment and the flex compartment. Additionally, a second return duct can connect to the freezer compartment and the icemaker compartment. The first return duct can direct a third air stream from the flex compartment to the evaporator. The second return duct can direct a fourth air stream from the icemaker compartment to the evaporator. The evaporator can cool the third air stream and the fourth air stream for cycling the third air stream and the fourth air stream back into the freezer compartment, icemaker compartment, flex compartment, or a combination thereof. In some examples, the first air stream and the second air stream can be cooler than the third air stream and the fourth air stream.
Illustrative examples are given to introduce the reader to the general subject matter discussed herein and are not intended to limit the scope of the disclosed concepts. The following sections describe various additional features and examples with reference to the drawings in which like numerals indicate like elements, and directional descriptions are used to describe the illustrative aspects, but, like the illustrative aspects, should not be used to limit the present disclosure.
Referring now to the figures of the drawings in detail and first, particularly to
The airflow system can be used for controlling temperature in the one or more compartments 110a-d. The airflow system can be placed in an interior of the refrigeration appliance 100. In some examples, the airflow system can be positioned horizontally in the first compartment 110a, the fourth compartment 110d, or a combination thereof. Additionally, the airflow system can be placed toward a back-side of the refrigeration appliance 100 proximate to an evaporator. In other examples, the airflow system can be positioned at other locations in the refrigeration appliance 100 or positioned vertically at a different angle relative to an axis of the refrigeration appliance 100.
As the flex compartment, the second compartment 110b can be set to a range of temperatures. For example, the second compartment 110b can be set to a temperature between zero and negative eighteen degrees Celsius, during which the second compartment 110b can be used as a freezer compartment. Additionally, the second compartment 110b can be set to a temperature between zero and four degrees Celsius, during which the second compartment 110b can be used as a refrigeration compartment. A temperature setting of the second compartment 110b can be chosen by the user via a setting button. A mainboard can be in communication with the setting button to receive the temperature setting or other suitable setting for the second compartment 110b. Additionally, a measured temperature of the second compartment 110b can be monitored by a sensor, such as a thermistor or other suitable sensor, positioned in the second compartment 110b. The mainboard can receive the measured temperature from the sensor. The mainboard may further control a damper, a fan, or other component of the airflow system based on a different between the temperature setting and the measured temperature.
Additionally, in some examples, the first compartment 110a and the fourth compartment 110d can include separate openings for a user to access the first compartment 110a or the fourth compartment 110d. An inside of the first compartment 110a and the fourth compartment 110d can be connected to create a single compartment. In some examples, the inside of the first compartment 110a and the fourth compartment 110d can be separated by a division plate or other suitable component. The single compartment provided by the first compartment 110a and the fourth compartment 110d can be a freezer compartment. In some examples, cooling of the second compartment 110b and cooling of the third compartment 110c can depend on the first compartment 110a, the fourth compartment 110d, or a combination thereof.
The airflow system can be at least partially positioned in the first compartment 110a, the fourth compartment 110d, or a combination thereof. Additionally, the airflow system can be at least partially positioned proximate to an evaporator in the first compartment 110a, the fourth compartment 110d, or a combination thereof. The evaporator can be a device with a cool surface for cooling air from the compartments 110a-d. The airflow system can control the cooling of the second compartment 110b by directing the air cooled by the evaporator via a first supply duct to the second compartment 110b. The airflow system can also control the cooling of the third compartment 110c by directing the air cooled by the evaporator via a second supply duct to the third compartment 110c. Additionally, a first return duct can cool the second compartment 110b by directing warm air from the second compartment 110b to the evaporator. A second return duct can cool the third compartment 110c by directing warm air from the third compartment 110c to the evaporator.
The first compartment 110a, the second compartment 110b and the third compartment 110c can be coupled with one or more supply ducts and one or more return ducts. As illustrated a first supply duct 304a can be coupled to a first backside 308a of the first compartment 110a and a second backside 308b of the second compartment 110b. A second supply duct 304b can be coupled to the first backside 308a of the first compartment 110a and a third backside 308c the third compartment 110c. A first return duct 306a can be coupled to the first backside 308a of the first compartment 110a and the second backside 308b of the second compartment 110b. Additionally, a second return duct 306b can be coupled to the first backside 308a of the first compartment 110a and the third backside 308c of the third compartment 110c.
In some examples, air can be directed between the first compartment 110a, the second compartment 110b and the third compartment 110c via the supply ducts 304a-b and the return ducts 306a-b. For example, air can be directed from the first compartment 110a to the second compartment 110b via the first supply duct 304a. Air can be directed from the first compartment 110a to the third compartment 110c via the second supply duct 304b. Additionally, air can be directed from the second compartment 110b to the first compartment 110a via the first return duct 306a. Air can further be directed from the third compartment 110c to the first compartment 110a via the second return duct 306b. The air directed by the return ducts 306a-b can be warmer than the air directed by the supply ducts 304a-b. Thus, the airflow system can maintain the temperatures of the first compartment 110a, the second compartment 110b and the third compartment 110c by providing cool air from the first compartment 110a to the second compartment 110b and third compartment 110c via supply ducts 304a-b and by removing warm air from compartments 310b-c via return ducts 306a-b.
The airflow system may also include a first housing and a second housing positioned inside the first compartment 110a. The first housing and the second housing can further be positioned proximate to an evaporator in the first compartment 110a. In an example, the evaporator is on a bottom side of the first compartment 110a. A first fan can be positioned in the first housing for distributing air cooled by the evaporator to the second compartment 110b via the first supply duct 304a. A second fan can also be positioned in the second housing for distributing air cooled by the evaporator to the third compartment 110c via the second supply duct 304b.
In some examples, the airflow system may not include housings or can include a different number of housings. Additionally, a damper can be positioned in, for example, the first housing. The damper may also be positioned in a supply duct, such as the first supply duct 304a. The damper can have a flap that can open and close. The flap may be positionable in a closed position to block airflow and may be positionable in an open position to allow airflow. Thus, a damper can further be used in the airflow system to control airflow to the first compartment 110a, second compartment 110b and third compartment 110c.
A second supply duct 304b can include a first opening of the second supply duct 416a, a second opening of the second supply duct 416b, and a third opening of the second supply duct 416c. The second supply duct 404b can be coupled to the first inner liner panel 408a and a third inner liner panel 408c. In an example, air can be directed from the first compartment to a third compartment via the second supply duct 304b. The first opening of the second supply duct 416a can be associated with the first compartment and the second opening of the second supply duct 416b and the third opening of the second supply duct 416c can be associated with the third compartment.
Additionally, a first return duct 306a can be coupled to the first inner liner panel 408a and the second inner liner panel 408b. The first return duct 306a include a first opening of the first return duct 412a that can be associated with the first compartment and a second opening of the first return duct 412b that can be associated with the second compartment. Air can be directed, via the first return duct 306a, from second compartment to the first compartment.
A second return duct 306b can be coupled to the first inner liner panel 408a and the third inner liner panel 408c. The second return duct 406b can include a first opening of the second return duct 414a and a second opening of the second return duct 414b. In an example, the first opening of the second return duct 414a can also be associated with the first compartment and the second opening of the second return duct 414b can be associated with the third compartment. Air can be directed from the third compartment to the first compartment via the second return duct 306b.
In some examples, the air directed through the return ducts 306a-b can be warmer than air directed through the supply ducts 304a-b. The air directed by the return ducts 306a-b can be directed to an evaporator in the refrigeration appliance. Additionally, air directed to compartments in the refrigeration appliance by supply ducts 304a-b can be cooled by the evaporator. The air cooled by the evaporator can be distributed by one or more fans of the airflow system. Thus, the evaporator can provide cool air for the refrigeration appliance, the fans can distribute the cool air to facilitate airflow through the supply ducts 304a-b, and warm air can be removed by the return ducts 306a-b to create an efficient airflow cycle.
The inner liner panels 408a-c can be positioned on a backside of a refrigeration appliance. In some examples, foam can be injected around the supply ducts 304a-b and return ducts 306a-b for insulating the supply ducts 304a-b and the return ducts 306a-b. Additionally, an outer liner panel can be placed over the inner liner panels such that the supply ducts 304a-b, the return ducts 306a-b, and the foam are between the inner liner panels 408a-c and the outer liner panel.
The use of the supply ducts 304a-b and the return ducts 306a-b in the airflow system can increase available space in compartments of the refrigeration appliance. Additionally, the use of the supply ducts 304a-b and the return ducts 306a-b and can reduce the complexity and number of parts involved in providing sufficient airflow to compartments in the refrigeration appliance. The supply ducts 304a-b and the return ducts 306a-b can further include reinforcement components 502 to protect the supply ducts 304a-b and the return ducts 306a-b from potential damage. For example, the reinforcement components 502 can prevent the foam from causing indentations in the supply ducts 304a-b or return ducts 306a-b. Additionally, the supply ducts 304a-b and the return ducts 306a-b can be composed of a plastic shell, insulating materials, a sealing component, other suitable components or materials, or a combination thereof.
The housing 600 may include a damper 606 positioned in the first geometry 602a. In some examples, the damper 606 can be positioned in the first supply duct 304a. Additionally, the damper 606 may be positioned in the first opening of the first supply duct 410a. The damper 606 can include a flap 608 that can be in a closed position to prevent airflow through the first opening of the first supply duct 410a or the first geometry 602a. The flap 608 can also be in an open position to allow airflow to the first supply duct 304a. The flap 608 can open or closed based on a temperature of a second compartment 110b. For example, a mainboard can receive a measured temperature for the second compartment 110b from a sensor. The mainboard can further receive a set temperature for the second compartment 110b. The mainboard can control the flap 608 by causing the flap 608 to be in the open position or the closed position based a difference between the set temperature and the measured temperature. The mainboard may control the flap 608 by sending a signal to the damper 606. The mainboard may further control a speed of the fan 604 based on the difference between the set temperature and the measured temperature. The mainboard may also control the speed by sending a signal to the fan 604.
In an example, the housing 600 can be a first housing and the airflow system can further include a second housing positioned in the first compartment. A first fan can be positioned in the first housing and second fan can be positioned in the second housing. The first housing can include a first damper that can have two flaps. A first flap can be positioned in the first opening and a second flap can be positioned in the second opening. The first flap and the second flap can open and close independently to selectively direct air to the first compartment, the supply duct, or a combination thereof. The second housing can include a third geometry that can define a third opening that can extend into the first compartment and a fourth geometry that can define a fourth opening that can extend into a second supply duct. A second damper can be positioned in the second housing that can also have two flaps. A third flap can be positioned in the third opening and a fourth flap can be positioned in the fourth opening. The third flap and the fourth flap can also open and close independently of one another to selectively direct air to the first compartment, the second supply duct, or a combination thereof.
Additionally or alternatively, dampers with one flap can be used for each opening of the first housing and the second housing. Additionally, in some examples, a different number of fans or fans of different type, size, shape, etc.
can be included in the first housing or the second housing. The airflow system may also include a different number of housings. The housings may be altered to include a different number of geometries, or the housings may be altered to include different or additional components. For example, the first fan, the second fan, the first damper, and the second damper can be positioned in a single housing. In other examples, the single housing can have a different number of fans or a different number of dampers. The single housing may further include different sizes or types of fans or different sizes or types of dampers.
In some examples, a damper can be positioned in the first geometry 602a, the first supply duct 304a, or the first opening of the first supply duct 410a. A flap of the damper can obstruct airflow to the second compartment 110b in a closed position or enable the airflow to the second compartment 110b in an open position. Additionally, the second compartment 110b can be a flex compartment that can be set to a range of temperatures. For example, the second compartment 704 can be set to a temperature between negative eighteen and four degrees Celsius. Therefore, the flap can be used to control airflow to the second compartment 110b to control the temperature of the second compartment 110b. A position of the flap can be based on a difference between a set temperature of the second compartment 110b and a temperature of the second compartment 110b detected by a sensor, such as a thermistor.
At first block 902, the airflow system 700 can generate, via an evaporator 706 positioned in a first compartment 110a of the refrigeration appliance, first air, by cooling, via the evaporator 706, the first air. The evaporator 706 can be a device with a cool surface that can cool air in the refrigeration appliance. In some examples, the first compartment 110a can be a freezer compartment. Additionally, the evaporator 706 can be positioned in a bottom portion of the first compartment 110a, can be positioned in a back portion of the first compartment 110a, or can be located elsewhere in the first compartment 110a.
At second block 904, the airflow system 700 can control a temperature of a second compartment 110b. The second compartment 110b can be a flex compartment in which the temperature can change. The temperature change may change the purpose of the flex compartment. For example, the flex compartment can be used as a freezer compartment or a refrigeration compartment.
At third block 906, the airflow system 700 can receive, via a mainboard, a temperature setting for the second compartment 110b. In some examples, the mainboard can provide a plurality of temperature settings for the second compartment 110b to a user. For example, the plurality of temperature settings can range from negative eighteen degrees Celsius to four degrees Celsius. The user may choose the temperature setting out of the plurality of temperature settings. In examples, the plurality of temperature settings can be associated with intended use of the second compartment 110b by the user. For example, the temperature settings provided to the user can be crisper, freezer, refrigeration, etc.
At fourth block 908, the airflow system 700 can receive, via the mainboard, a measured temperature detected by a sensor for the second compartment 110b. The sensor can be a thermistor or other suitable sensor. In some examples, the mainboard can receive the measured temperature as a change in temperature of the second compartment 110b detected by the sensor or the mainboard can receive the measured temperature as the current temperature of the second compartment 704.
At fifth block 910, the airflow system 700 can control, by the mainboard, a flap of a damper based on a difference between the temperature setting and the measured temperature. The damper can be positioned in a first supply duct 304a, in a housing 600, in a first opening of the first supply duct 410a associated with the first supply duct 304a, or otherwise positioned in the airflow system 700. The flap of the damper can have an open position and a closed position. The mainboard can control the flap by sending a signal to the damper to cause the flap to move to the open position or the closed position. In an example, the measured temperature of the second compartment 110b can be higher than the temperature setting. Therefore, the mainboard can cause the flap to open to enable air to reach the first supply duct 304a. The mainboard can further cause the flap to close when the measured temperature decreases to the temperature setting. Additionally, there can be a threshold for which the measured temperature and the temperature setting can be different. For example, the threshold can be half of a degree Celsius. Therefore, for example, while the measured temperature is within a half of a degree Celsius of the temperature setting the mainboard can cause the flap to be in the closed position.
At sixth block 912 the airflow system 700 can direct, via the first supply duct 304a coupled to the first compartment 110a and the second compartment 110b, the first air flow from the first compartment 110a to the second compartment 110b. In an example, the first compartment 110a can be a freezer compartment and the second compartment 110b can be a full flex compartment. Additionally, the airflow system 700 can include the housing 600 that can be positioned in the first compartment 110a proximate to the evaporator 706. The housing 600 can have a first geometry 602a that can extend into the first supply duct 304a. The housing 600 can also have a second geometry 602b that can extend into the first compartment 110a. Therefore, the first air flow can have two airflow paths as provided by the housing 600. The first airflow path can be through the first geometry 602a and the first opening of the first supply duct 410a to the first supply duct 304a. The damper may enable or block the first airflow path via the flap. The second airflow path can be through the second geometry 602b to the first compartment 110a. A fan 604 can be positioned in the housing 600 for distributing air to the first airflow path and second airflow path. The mainboard may also control a speed of the fan 604 based on the difference between the temperature setting and the measured temperature.
At seventh block 914 the airflow system 700 can direct, via a first return duct 306a coupled to the first compartment 110a and the second compartment 110b, a second air flow from the second compartment 110b to the evaporator 706. The second air flow can be warmer than a temperature setting of the second compartment 110b. The second air flow may also be warmer than the first air flow. Therefore, the first return duct 306a can remove the second air flow from the second compartment 110b to cool the second compartment 110b. By providing the first air flow to the second compartment 110b via the first supply duct 304a and removing the second air flow from the second compartment 110b via the first return duct 306a, the airflow system 700 can create an efficient airflow cycle for controlling the temperature of the second compartment 110b.
Additionally or alternatively, process 900 can include, the airflow system 700 directing, via a second supply duct 304b coupled to the first compartment 110a and a third compartment 110c, third air from the first compartment 110a to the third compartment 110c. In an example, the third compartment 110c can be an icemaker compartment and the third compartment 110c may be a same or similar temperature as the first compartment 110a. The third air flow can also be cooled by the evaporator 706. Therefore, the temperatures of the second compartment 110b and the third compartment 110c can depend on the evaporator 706 in the first compartment 110a. The use of the supply ducts 304a-b can decrease the number of evaporators, fans, etc. used in the refrigeration appliance to provide cool air to various compartments. Additionally, the second compartment 110b can be a different temperature than the first compartment 110a and the third compartment 110c as the airflow system 700 can use the damper to control airflow to the second compartment 110b.
In some examples, the airflow system 700 can further include a second fan for distributing the third air flow. The second fan can be positioned in the housing 600 or positioned in a second housing. The second housing can have a third geometry that can define a third opening extending into the second supply duct. The second housing can also have a fourth geometry that can define a fourth opening extending into the first compartment 110a.
Additionally, the airflow system 700 can direct, via a second return duct coupled to the first compartment 110a and the third compartment 110c, the fourth air flow from the third compartment to the evaporator 706. The fourth air flow can be warmer than a temperature setting of the third compartment. Therefore, the second return duct can remove the fourth air flow from the third compartment to cool the third compartment. Additionally, by providing the third air flow to the third compartment via the second supply duct and removing the fourth air flow via the second return duct, the airflow system 700 can create an efficient airflow cycle for controlling the temperature of the third compartment.
In some examples, additional or fewer supply ducts or return ducts can be used to control the temperature of additional or fewer compartments. Additionally, a different number of housings, fans, or dampers can be implemented in a compartment with an evaporator to efficiently direct air to the supply ducts, compartments, or a combination thereof.
The foregoing description of certain examples, including illustrated examples, has been presented only for the purpose of illustration and description and is not intended to be exhaustive or to limit the disclosure to the precise forms disclosed. Numerous modifications, adaptations, and uses thereof will be apparent to those skilled in the art without departing from the scope of the disclosure.
The following is a summary list of reference numerals and the corresponding structure used in the above description of the invention:
Number | Date | Country | Kind |
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2022/016327 | Oct 2022 | TR | national |
This application claims the priority, under 35 U.S.C. § 119, of Turkish Patent Application TR 2022/016327, filed Oct. 27, 2022; the prior application is herewith incorporated by reference in its entirety.