Pursuant to 35 U.S.C. §119(a), this application claims the benefit of earlier filing date and right of priority to Korean Application No. 10-2015-0158325, filed on Nov. 11, 2015, the contents of which is incorporated by reference herein in its entirety.
1. Field of the Invention
The present disclosure relates to a defrosting device for removing frost formed on an evaporator provided in a refrigeration cycle, and a refrigerator having the same.
2. Description of the Related Art
An evaporator provided in a refrigeration cycle decreases ambient temperature using cool air generated by the circulation of coolant flowing through a cooling tube. During the process, when there occurs a temperature difference from ambient air, a phenomenon of condensing and freezing moisture in the air on a surface of the cooling tube occurs.
A defrosting method using an electric heater has been used for a defrosting process for removing frost formed on an evaporator in the related art.
In recent years, a defrosting device using a heat pipe has been developed and contrived, and the related technologies include Korean Patent Registration No. 10-0469322, entitled “Evaporator.”
In a heat pipe type defrosting device, working fluid heated by a heating unit is configured to circulate a heat pipe, and heat emission is carried out on a cooling tube during the circulation process of working fluid. Due to the flow of the working fluid, as working fluid transfers heat to the cooling tube, temperature may gradually decrease, and thus defrosting may not be efficiently carried out for a lower cooling tube.
In particular, considering that frost is mostly formed at a front side of the evaporator due to the flow of cool air, increasing the temperature of the heat pipe may be an important issue in defrosting reliability.
An aspect of the present disclosure is to provide a defrosting device capable of increasing the entire temperature of the heat pipe to perform efficient defrosting.
Another aspect of the present disclosure is to provide a defrosting device capable of transferring more heat to a first heat pipe disposed at a front portion of the evaporator, considering that frost is mostly formed at a front side of the evaporator due to the flow of cool air.
In order to accomplish the foregoing tasks of the present disclosure, a defrosting device according to the present disclosure may include a heating unit provided at a lower side of an evaporator, and configured to heat working fluid therein; and a plurality of heat pipes, both end portions of which are connected to an inlet and an outlet of the heating unit, respectively, and at least part of which are disposed adjacent to a cooling tube of the evaporator to emit heat to the cooling tube due to high temperature working fluid heated and transferred by the heating unit, wherein the plurality of heat pipes are configured with a first heat pipe and a second heat pipe disposed to form two rows on a front portion and a rear portion of the evaporator, respectively, and the first heat pipe and the second heat pipe are formed in different lengths.
The first and the second heat pipe may be repeatedly bent in a zigzag shape, respectively, to form a plurality of columns, and the first heat pipe and the second heat pipe may be configured to have different total numbers of columns.
The present disclosure discloses a first and a second embodiment of the first and the second heat pipe provided in the defrosting device.
A total number of columns of the second heat pipe may be configured to be less than that of the first heat pipe.
For an example, the highest and the lowest column of the second heat pipe may be disposed to correspond to the highest and the lowest column of the first heat pipe, respectively, and a distance between two columns adjacent to each other on the second heat pipe may be larger than that between two columns adjacent to each other on the first heat pipe.
For another example, the highest column of the second heat pipe may be disposed to be lower than the highest column of the first heat pipe, and a distance between two columns adjacent to each other on the second heat pipe may be configured to correspond to that between two columns adjacent to each other on the first heat pipe.
A total number columns of the first heat pipe may be configured to be less than that of the second heat pipe.
For an example, the highest and the lowest column of the first heat pipe may be disposed to correspond to the highest and the lowest column of the second heat pipe, respectively, and a distance between two columns adjacent to each other on the first heat pipe may be larger than that between two columns adjacent to each other on the second heat pipe.
For another example, the highest column of the first heat pipe may be disposed to be lower than the highest column of the second heat pipe, and a distance between two columns adjacent to each other on the first heat pipe may be configured to correspond to that between two columns adjacent to each other on the second heat pipe.
Moreover, the present disclosure discloses a first and a second embodiment of a heating unit provided in the defrosting device.
The heating unit may include a heater case provided with a vacant space therein, and provided with the inlet and the outlet, respectively, at positions separated from each other along a length direction; and a heater attached to an outer surface of the heater case to heat working fluid within the heater case.
The heater may include a base plate formed of a ceramic material, and attached to an outer surface of the heater case; a heating element formed on the base plate, and configured to emit heat during the application of power; and a terminal provided on the base plate to electrically connect the heating element to the power.
The heater case may be partitioned into an active heating part corresponding to a portion on which the heating element is disposed and a passive heating part corresponding to a portion on which the heating element is not disposed, and the inlet may be formed on the passive heating part to prevent working fluid moving through the heat pipe and then returning through the inlet from being reheated and flowing backward.
The heater may be attached to a bottom surface of the heater case, and a first and a second extension fin extended from the bottom surface in a downward direction to cover both sides of the heater attached to the bottom surface may be provided at both sides of the heater case, respectively.
A sealing member may be filled into a recessed space formed by a rear surface of the heater and the first and the second extension fin to cover the heater, and an insulating material may be interposed between the rear surface of the heater and the sealing member.
The heating unit may include a heater case provided with a vacant space therein, and provided with the inlet and the outlet, respectively, at positions separated from each other along a length direction; and a heater having an active heating part accommodated in the heater case to actively generate heat so as to heat working fluid, and a passive heating part extended from the active heating part to be heated at a temperature lower than that of the active heating part, wherein the inlet is formed at a position facing the passive heating part on an outer circumference of the heater case to introduce working fluid moving through the heat pipe and then returning into a space between the heater case and the passive heating part.
In addition, the present disclosure discloses a refrigerator, including a refrigerator body; an evaporator provided within the refrigerator to absorb ambient heat as the heat of vaporization to perform a cooling function; and a defrosting device configured to remove frost generated on the evaporator.
According to the present disclosure, either one of the first and the second heat pipe should be formed to be shorter than the other one thereof, and thus the entire path through which working fluid circulates may be shorter, thereby increasing the temperatures of the first and the second heat pipe as a whole. As a result, it may be possible to enhance defrost performance.
A total number of columns of the second heat pipe disposed on a rear portion of the evaporator may be configured to be less than that of the first heat pipe disposed on a front portion of the evaporator, considering that frost is mostly formed at a front side of the evaporator due to the flow of cool air. According to this, a path through which working fluid (F) circulates may be shorter to increase the temperature of the first and the second heat pipe as a whole, and a total number of columns of the first heat pipe may be provided to be larger than that of the second heat pipe, thereby transferring more heat through the first heat pipe.
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention.
In the drawings:
Hereinafter, a defrosting device and a refrigerator having the same associated with the present disclosure will be described in more detail with reference to the accompanying drawings.
According to the present specification, the same or similar elements are designated with the same numeral references even in different embodiments and their redundant description will be omitted.
Furthermore, a structure applied to any one embodiment may be also applied in the same manner to another embodiment if they do not structurally or functionally contradict each other even in different embodiments.
A singular representation may include a plural representation as far as it represents a definitely different meaning from the context.
In describing the embodiments disclosed herein, moreover, the detailed description will be omitted when a specific description for publicly known technologies to which the invention pertains is judged to obscure the gist of the present invention.
The accompanying drawings are used to help easily understand various technical features and it should be understood that the embodiments presented herein are not limited by the accompanying drawings. As such, the present disclosure should be construed to extend to any alterations, equivalents and substitutes in addition to those which are particularly set out in the accompanying drawings.
The refrigerator 100 is a device for storing foods kept therein at low temperatures using cooling air generated by a less in which the processes of compression-condensation-expansion-evaporation are sequentially carried out.
As illustrated in the drawing, a refrigerator body 110 may include a storage space for storing foods therein. The storage space may be separated by a partition wall 111, and divided into a refrigerating chamber 112 and a freezing chamber 113 according to the set temperature.
According to the embodiment, a top mount type refrigerator in which the freezing chamber 113 is disposed on the refrigerating chamber 112, but the present disclosure may not be necessarily limited to this. The present disclosure may be applicable to a side by side type refrigerator in which the refrigerating chamber and freezing chamber are horizontally disposed, a bottom freezer type refrigerator in which the refrigerating chamber is provided at the top and the freezing chamber is provided at the bottom, and the like.
A door is connected to the refrigerator body 110 to open or close a front opening portion of the refrigerator body 110. According to the present drawing, it is illustrated that a refrigerating chamber door 114 and a freezing chamber door 115 are configured to open or close a front portion of the refrigerating chamber 112 and freezing chamber 113, respectively. The door may be configured in various ways, such as a rotation type door in which a door is rotatably connected to the refrigerator body 110, a drawer type door in which a door is slidably connected to the refrigerator body 110, and the like.
The refrigerator body 110 may include at least one of accommodation units 180 (for example, a shelf 181, a tray 182, a basket 183, etc.) for effectively using an internal storage space. For example, the shelf 181 and tray 182 may be installed within the refrigerator body 110, and the basket 183 may be installed at an inside of the door 114 connected to the refrigerator body 110.
On the other hand, a machine room 117 is provided in the refrigerator body 110, and a compressor 160, a condenser (not shown) and the like are provided within the machine room 117. The compressor 160 and the condenser are connected to an evaporator 130 provided in the cooling chamber 113 to constitute a refrigeration cycle. Refrigerant circulating the refrigeration cycle absorbs ambient heat as the heat of vaporization, thereby allowing the surroundings to obtain a cooling effect.
A refrigerating chamber return duct 111a and a freezing chamber return duct 111b for inhaling and returning the air of the refrigerating chamber 112 and freezing chamber 113 to the side of the cooling chamber 116 are formed on the partition wall 111. Furthermore, a cool air duct 150 communicating with the freezing chamber 113 and having a plurality of cool air discharge ports 150a on a front portion thereof is installed at a rear side of the refrigerating chamber 112.
On the other hand, the process of inhaling the air of the refrigerating chamber 112 and freezing chamber 113 to the cooling chamber 116 through the refrigerating chamber return duct 111a and freezing chamber return duct 111b of the partition wall 111 by the blower fan 140 of the cooling chamber 116 to perform heat exchange with the evaporator 130, and discharging it to the refrigerating chamber 112 and freezing chamber 113 through the cool air discharge ports 150a of the cool air duct 150 again is repeatedly carried out. At this time, frost is formed on a surface of the evaporator 130 due to a temperature difference from circulation air reintroduced through the refrigerating chamber return duct 111a and the freezing chamber return duct 111b.
A defrosting device 170 is provided in the evaporator 130 to remove such frost, and water removed by the defrosting device 170, namely, defrost water, is collected to a lower defrost water tray (not shown) of the refrigerator body 110 through a defrost water discharge pipe 118.
Hereinafter, a new type of defrosting device 170 capable of reducing power consumption and enhancing heat exchange efficiency during defrost will be described.
For reference, part of a second heat pipe 172″ overlaps with a first heat pipe 172′ and thus not seen in
Referring to
The cooling tube 131 is repeatedly bent in a zigzag shape to constitute a plurality of columns, and refrigerant is filled therein. The cooling tube 131 may be formed in an aluminum material.
The cooling tube 131 may be configured in combination with horizontal pipe portions and bending pipe portions. The horizontal pipe portions are horizontally disposed to each other in a vertical direction, and configured to pass through the cooling fins 132, and the bending pipe portions couples an end portion of an upper horizontal pipe portion to an end portion of a lower horizontal pipe portion to communicate their inner portions with each other.
The cooling tube 131 is supported through the support fixture 133 provided at both sides of the evaporator 130. Here, the bending pipe portion of the cooling tube 131 is configured to couple an end portion of an upper horizontal pipe portion to an end portion of a lower horizontal pipe portion at an outer side of the support fixture 133.
According to the present embodiment, it is seen that the cooling tube 131 is configured with a first cooling tube 131′ and a second cooling tube 131″ formed at a front portion and a rear portion of the evaporator 130, respectively, to constitute two columns. For reference, the first cooling tube 131′ at a front side thereof and the second cooling tube 131″ at a rear side thereof are formed with the same shape, and thus the second cooling tube 131″ is hidden by the first cooling tube 131′ in
However, the present disclosure may not be necessarily limited to this. The first cooling tube 131′ at a front side thereof and the second cooling tube 131″ at a rear side thereof may be formed in different shapes. On another hand, the cooling tube 131 may be formed to constitute a single column.
For the cooling tube 131, a plurality of cooling fins 132 are disposed to be separated at predetermined intervals along an extension direction of the cooling tube 131. The cooling fin 132 may be formed with a flat body made of an aluminum material, and the cooling tube 131 may be flared in a state of being inserted into an insertion hole of the cooling fin 132, and securely inserted into the insertion hole.
A plurality of support fixtures 133 may be provided at both sides of the evaporator 130, respectively, and each of which is configured to support the cooling tube 131 vertically extended and passed through along a vertical direction. An insertion groove or insertion hole to which a heat pipe 172 which will be described later can be inserted and fixed is formed on the support fixture 133.
The defrosting device 170 is provided in the evaporator 130 to remove frost generated from the evaporator 130. The defrosting device 170 may include a heating unit 171 and a heat pipe 172 (heat transfer tube).
The heating unit 171 is provided at a lower side of the evaporator 130, electrically connected to the controller (not shown), and formed to generate heat upon receiving a drive signal from the controller. For example, the controller may be configured to apply a drive signal to the heating unit 171 for each predetermined time interval or apply a drive signal to the heating unit 171 when the sensed temperature of the cooling chamber 116 is less than a predetermined temperature.
The heat pipe 172 is connected to the heating unit 171 to form a closed loop shaped passage through which working fluid (F) can circulate along with the heating unit 171. The heat pipe 172 is formed of an aluminum material.
At least part of the heat pipe 172 is disposed adjacent to the cooling tube 131 of the evaporator 130, and configured to transfer heat to the cooling tube 131 of the evaporator 130 due to high temperature working fluid (F) heated and transferred by the heating unit 171 to remove frost.
For the working fluid (F), refrigerant (for example, R-134a, R-600a, etc.) that exists in the liquid phase in a freezing condition of the refrigerator 100, but is phase-changed into the gas phase to perform the role of transferring heat when heated by the heater 171b may be used.
The heat pipe 172 is repeatedly bent in a zigzag shape similarly to the cooling tube 131 to constitute a plurality of columns. To this end, the heat pipe 172 may include an extension portion 172a and a heat emitting part 172b.
The extension portion 172a forms a passage for transferring working fluid (F) heated by the heating unit 171 in an upward direction of the evaporator 130. The extension portion 172a is coupled to an outlet 171c′, 171c″ of the heater case 171a provided at the lower side of the evaporator 130 and the heat emitting part 172b provided on the evaporator 130 (refer to
The extension portion 172a may include a vertical extension portion extended in an upward direction of the evaporator 130. The vertical extension portion is extended up to an upper portion of the evaporator 130 in a state of being disposed to be separated from the support fixture 133 at an outer side of the support fixture 133 provided at one side of the evaporator 130.
On the other hand, the extension portion 172a may further include a horizontal extension portion according to the installation position of the heating unit 171. For an example, when the heating unit 171 is provided at a position separated from the vertical extension portion (i.e., when the heating unit 171 is disposed adjacent to the right support fixture 133 on the drawing), a horizontal extension portion for coupling the heating unit 171 to the vertical extension portion may be additionally provided.
When the horizontal extension portion is coupled to the heating unit 171 and extended in an elongated manner, high temperature working fluid (F) may pass through a lower portion of the evaporator 130, thereby having an advantage of efficiently implementing defrost operations on the cooling tube 131 at a lower side of the evaporator 130.
The heat emitting part 172b is coupled to the extension portion 172a extended to an upper portion of the evaporator 130, and extended in a zigzag shape along the cooling tube 131 of the evaporator 130. The heat emitting part 172b is configured in combination with a plurality of horizontal tubes 172b1 constituting columns and a connecting tube 172b2 formed in a bent U-shaped tube to connect them in a zigzag shape.
The extension portion 172a and heat emitting part 172b may be extended up to a position adjacent to an accumulator 134 to remove frost formed on the accumulator 134.
As illustrated in the drawing, when the vertical extension portion is disposed at one side of the evaporator 130 at which the accumulator 134 is located, the vertical extension portion may be extended upward to a position adjacent to the accumulator 134, and then bent and extended downward toward the cooling tube 131 to be coupled to the heat emitting part 172b.
On the contrary, when the vertical extension portion is disposed at the other side opposite to the one side, the heat emitting part 172b may be coupled to the vertical extension portion and extended in a horizontal direction, and then extended upward toward the accumulator 134, and then extended downward again to correspond to the cooling tube 131.
The heat pipe 172 may be accommodated between a plurality of cooling fins 132 fixed to each column of the cooling tube 131. According to the foregoing structure, the heat pipe 172 is disposed between each column of the cooling tube 131. Here, the heat pipe 172 may be configured to make contact with the cooling fin 132.
However, the present disclosure may not be necessarily limited to this. For an example, the heat pipe 172 may be provided to pass through a plurality of cooling fins 132. In other words, the heat pipe 172 may be flared in a state of being inserted into an insertion hole of the cooling fin 132, and securely inserted into the insertion hole. According to the foregoing structure, the heat pipe 172 is disposed to correspond to the cooling tube 131.
For the heat pipe 172, a portion coupled to the outlet 171c′. 171c″ of the heater case 171a constitutes an entrance portion 172c′, 172c″ for introducing high temperature working fluid (F), and a portion coupled to the inlet 171d′, 171d″ of the heater case 171a constitutes a return portion 172d′, 172d″ for returning the cooled working fluid (F) (refer to
According to the present embodiment, working fluid (F) heated by the heater 171b forms a circulation loop in which the working fluid (F) is discharged to the entrance portion 172c′, 172c″ and transferred to an upper portion of the evaporator 130 through the extension portion 172a, and then heat is transferred to the cooling tube 131 while flowing along the heat emitting part 172b to perform a defrost operation, and then the working fluid (F) is returned through the return portion 172d′, 172d″, and reheated by the heater 171b again to flow the heat pipe 172 (refer to
On the other hand, the heat pipe 172 may include a first heat pipe 172′ and a second heat pipe 172″ disposed on a front portion and a rear portion of the evaporator 130, respectively, to form two rows. According to the present embodiment, it is illustrated that the first heat pipe 172′ is disposed at a front side of the first cooling tube 131′, and the second heat pipe 172″ is disposed at a rear side of the second cooling tube 131″ to form two rows.
The first heat pipe 172′ and second heat pipe 172″ are formed with different lengths. In other words, either one of the first and the second heat pipe 172′, 172″ is formed to be shorter than the other one. According to this, the entire path through which working fluid (F) circulates becomes shorter to increase the temperature of the first and the second heat pipe 172′, 172″ as a whole. As a result, it may be possible to enhance defrost performance.
The first heat pipe 172′ and the second heat pipe 172″ may be configured to have different total number of columns to form the first and the second heat pipe 172′, 172″ with different lengths.
For an example, a total number of columns of the second heat pipe 172″ disposed on a rear portion of the evaporator 130 may be configured to be less than that of the first heat pipe 172′. Here, the total number of columns denotes a total number of columns formed by a plurality of horizontal tubes 172b1 on the heat emitting part 172b constituting the heat pipe 172.
According to the foregoing structure, a path through which working fluid (F) circulates may be shorter to increase the temperature of the first and the second heat pipe 172′, 172″ as a whole as well as the first heat pipe 172′ may have a larger total number of columns than that of the second heat pipe 172″, thereby transferring more heat through the first heat pipe 172′. It may be an efficient structure, considering that frost is mostly formed at a front side of the evaporator due to the flow of cool air.
According to the present drawing, it is shown that the first heat pipe 172′ is configured with total eight columns, and the second heat pipe 172″ is configuration with total six columns. Specifically, in a state that the highest and the lowest column of the second heat pipe 172″ are disposed to correspond to the highest and the lowest column of the first heat pipe 172′, respectively, a distance between two columns adjacent to each other on the second heat pipe 172″ is larger than that between two columns adjacent to each other on the first heat pipe 172′.
The two adjoining columns of the second heat pipe 172 may be provided at an upper portion of the second heat pipe 172″. According to the foregoing structure, a distance between two adjoining columns of the lower portion may be formed to be less than that of two adjoining columns of the upper portion. It is a design considering convection according to the temperature of working fluid (F) when the working fluid (F) circulates through the second heat pipe 172″.
Specifically, working fluid (F) introduced through the entrance portion 172c′, 172c″ of the heat pipe 172 has the highest temperature during the circulation process of the heat pipe 172 in the gas phase at high temperatures. As illustrated in the drawing, the high-temperature working fluid (F) moves to the side of the cooling tube 131 located at an upper portion, and thus high-temperature heat is transferred to a large area by convention in the vicinity of the cooling tube 131 at the upper portion.
On the contrary, working fluid (F) flows in a state liquid and gas coexist while gradually dissipating heat, and as a result, is introduced into the return portion 172d′, 172d″ in the liquid phase, wherein heat at this time is a sufficient temperature for removing the frost of the cooling tube 131, but the extent of transferring heat transfer to the surrounding medium is lower as compared to the foregoing case.
Accordingly, in consideration of this, each column of the second heat pipe 172″ adjacent to the return portion 172d′, 172d″ (i.e., a horizontal tube 172b1 of the heat emitting part 172b) is disposed at smaller intervals compared to each column of the second heat pipe 172″ located at the upper portion. For example, each column of the second heat pipe 172″ located at the upper portion may be disposed to correspond to the column of an adjoining cooling tube 131 by interposing one column of the cooling tube 131 therebetween, and each column of the second heat pipe 172″ located at the lower portion may be disposed to correspond to each column of the cooling tube 131. According to the foregoing structure, each column (i.e., the horizontal tube 172b1 of the heat emitting part 172b) of the second heat pipe 172″ is arranged at a lower portion of the evaporator 130 in a relatively larger number than that of an upper portion thereof.
According to the foregoing structure, even when it is configured that a number of columns of the second heat pipe 172″ is less than that of the first heat pipe 172′, defrosting on a rear portion of the evaporator 130 may be efficiently carried out by the effective layout of the second heat pipe 172″.
On the other hand, the present disclosure may not be necessarily limited to this. The highest column of the second heat pipe 172″ may be disposed to be lower than the highest column of the first heat pipe 172′ or the lowest column of the second heat pipe 172″ may be disposed to be higher than the lowest column of the first heat pipe 172′. In this case, a distance between two columns adjacent to each other on the second heat pipe 171″ may be formed to correspond to (to be the same or similar to) that between two columns adjacent to each other on the first heat pipe 172′.
Hereinafter, the heating unit 171 applied to the foregoing structure will be described.
Referring to the present drawings along with the foregoing drawings, the heating unit 171 may include a heater case 171a and a heater 171b.
The heater case 171a has a hollow shape therein, and is coupled to both end portions of the heat pipe 172, respectively, to form a closed loop shaped passage through which working fluid (F) can circulate along with the heat pipe 172. The heater case 171a may have a rectangular pillar shape, and formed of an aluminum material.
The heater case 171a may be disposed at one side of the evaporator 130 at which the accumulator 134 is located, the other side opposite the one side, or at any point between the one side and the other side.
The heater case 171a may be disposed adjacent to the lowest column of the cooling tube 131. For example, the heater case 171a may be disposed at the same height as the lowest column of the cooling tube 131 or disposed at a position lower than the lowest column of the cooling tube 131.
In
The outlet 171c′, 171c″ and the inlet 171d′, 171d″ coupled to both end portions of the heat pipe 172, respectively, are formed at both sides of the heater case 171a, respectively, in a length direction.
Specifically, the outlet 171c′, 171c″ communicated with one end portion of the heat pipe 172 is formed at one side of the heater case 171a (for example, an outer circumferential surface adjacent to a front end portion of the heater case 171a). The outlet 171c′, 171c″ denotes an opening through which working fluid (F) heated by the heater 171b is discharged to the heat pipe 172.
The inlet 171d′, 171d″ communicated with the other end portion of the heat pipe 172 is formed at the other side of the heater case 171a (for example, an outer circumferential surface adjacent to a rear end portion of the heater case 171a). The inlet 171d′, 171d″ denotes an opening through which condensed working fluid (F) is collected to the heater case 171a while passing through the heat pipe 172.
The heater 171b is attached to an outer surface of the heater case 171a, and configured to generate heat upon receiving a drive signal from the controller. Working fluid (F) within the heater case 171a receives heat due to the heater 171b to be heated at high temperatures.
The heater 171b is extended and formed along one direction, and has a shape of being attached to an outer surface of the heater case 171a and extended along a length direction of the heater case 171a. A plate-shaped heater (for example, a plate-shaped ceramic heater) having a plate shape is used for the heater 171b.
According the present embodiment, the heater case 171a is formed in a rectangular pipe shape in which a vacant space therein has a rectangular cross-sectional shape, and it is shown that a plate-shaped heater 171b is attached to a bottom surface of the heater case 171a. In this manner, the structure in which the heater 171b is attached to a bottom surface of the heater case 171a may be beneficial in generating a driving force in an upward direction on the heated working fluid (F), and defrost water generated due to the defrost operation may not directly fall onto the heater 171b, thereby preventing a short circuit.
A heating element 171b2 (refer to
The heat pipe 172 and heater case 171a may be formed of the same type material (for example, aluminum material), and in this case, the heat pipe 172 may be coupled to the outlet 171c′, 171c″ and the inlet 171d′, 171d″ of the heater case 171a.
For reference, when the heater 171b is configured with a cartridge type and mounted within the heater case 171a, the heater case 171a with a copper material other than an aluminum material will be used to bond and seal between the heater 171b and the heater case 171a.
In this manner, when the heat pipe 172 and the heater case 171a are formed of different types of materials (as described above, when the heat pipe 172 is formed of an aluminum material, and the heater case 171a is formed of a copper material), it is difficult to directly connect the heat pipe 172 to the outlet 171c′, 171c″ and the inlet 171d′, 171d″ of the heater case 171a. Accordingly, for the connection between them, an outlet tube is extended and formed to the outlet 171c′, 171c″ of the heater case 171a, and a return tube is extended and formed to the inlet 171d′, 171d″ to connect the heat pipe 172 to the outlet tube and the return tube, and thus the bonding and sealing process is required for the procedure.
However, according to a structure in which the heater 171b is attached to an outer surface of the heater case 171a, the heater case 171a may be formed of the same material as that of the heat pipe 172, and the heat pipe 172 may be directly coupled to the outlet 171c′, 171c″ and the inlet 171d′, 171d″ of the heater case 171a.
On the other hand, as working fluid (F) filled into the heater case 171a is heated to high temperatures by the heater 171b, the working fluid (F) flows due to a pressure difference to move the heat pipe 172. Specifically, the working fluid (F) at high temperatures heated by the heater 171b and discharged to the outlet 171c′, 171c″ transfers heat to the cooling tube 131 of the evaporator 130 while moving through the heat pipe 172. The working fluid (F) is gradually cooled while passing through the heat exchange process and introduced into the inlet 171d′, 171d″. The cooled working fluid (F) is reheated by the heater 171b and then discharged to the outlet 171c′, 171c″ again to repeatedly perform the foregoing processes. The defrosting of the cooling tube 131 is carried out due to such a circulation method.
According to a structure in which the heat pipe 172 is configured with the first and the second heat pipe 172′, 172″, the first and the second heat pipe 172′, 172″ are coupled to the inlet 171d′, 171d″ and the outlet 171c′, 171c″ of the heating unit 171, respectively.
Specifically, the outlet 171c′, 171c″ of the heating unit 171 is configured with a first outlet 171c′ and a second outlet 171c″, and one end portion of the first and the second heat pipe 172′, 172″, respectively, is coupled to the first and the second outlet 171c′, 171c″, respectively. Due to the foregoing connection structure, working fluid (F) in the gas phase heated by the heating unit 171 is discharged to the first and the second heat pipe 172′, 172″, respectively, through the first and the second outlet 171c′, 171c″.
The first and the second outlet 171c′, 171c″ may be formed at both sides of an outer circumference of the heater case 171a, respectively, and formed in parallel at a front portion of the heater case 171a.
It may be understood that one end portion of the first and the second heat pipe 172′, 172″ coupled to the first and the second outlet 171c′, 171c″, respectively, is the first and the second entrance portions 172c′, 172c″ (a portion to which working fluid (F) at high temperatures heated by the heater 171b is introduced) due to the function.
Furthermore, the inlet 171d′, 171d″ of the heating unit 171 is configured with a first inlet 171d′ and a second inlet 171d″, and the other end of the first and the second heat pipe 172′, 172″, respectively, is coupled to the inlet 171d′, 171d″, respectively. Due to the connection structure, working fluid (F) in the liquid phase cooled while moving the heat pipes 172, respectively, is introduced into the heater case 171a through the inlet 171d′, 171d″.
The inlet 171d′, 171d″ may be formed at both sides of an outer circumference of the heater case 171a, respectively, and formed in parallel at a rear portion of the heater case 171a.
It may be understood that the other end portion of the first and the second heat pipe 172′, 172″ coupled to the inlet 171d′, 171d″, respectively, is the first and the second return portions 172d′, 172d″ (a portion to which working fluid (F) in the liquid phase cooled while moving through the heat pipes 172, respectively, is collected) due to the function.
On the other hand, referring to
The heating element 171b2 of the heater 171b may be extended and formed from one point between the inlet 171d′, 171d″ and the outlet 171c′, 171c″ to a position passed through the outlet 171c′, 171c″. According to this, the outlet 171c′, 171c″ of the heater case 171a is located within the active heating part (AHP).
Due to the foregoing structure, part of working fluid (F) stays at a front end portion (a space between an inner front end and the outlet 171c′, 171c″ of the heater case 171a) to prevent the overheating of the heater 171b.
Specifically, working fluid (F) heated by the active heating part (AHP) moves in a direction through which the working fluid (F) circulates, namely, toward a front end portion of the heater case 171a, and during this process, part of the working fluid (F) is discharged to the branched outlet 171c′, 171c″, but the remaining working fluid passes through the outlet 171c′, 171c″ and stays while forming a vortex at a front end portion of the heater case 171a.
In this manner, the whole of the heated working fluid (F) is not immediately discharged to the outlet 171c′, 171c″, but part thereof stays within the heater case 171a without being immediately discharged to the outlet 171c′, 171c″, thereby further preventing the overheating of the heater 171b.
As described above, the heater 171b applied to the heating unit 171 of the present disclosure may be formed in a plate shape, and a plate-shaped ceramic heater 171b may be typically used.
As illustrated in
The base plate 171b1 is formed of a ceramic material, and formed in a plate shape extended in an elongated manner along one direction. The base plate 171b1 is attached to an outer surface of the heater case 171a, and disposed along a length direction of the heater case 171a.
The heating element 171b2 is formed on the base plate 171b1, and the heating element 171b2 is configured to emit heat during the application of power. In a state that the base plate 171b1 is attached to an outer surface of the heater case 171a, the heating element 171b2 has a shape of being extended from one point between the inlet 171d′, 171d″ and the outlet 171c′, 171c″ toward the outlet 171c′, 171c″.
The heating element 171b2 may be formed by patterning a resistor *for example, powder mixed with ruthenium and platinum, tungsten, etc.) on the base plate 171b1 with a specific pattern. The heating element 171b2 may be extended and formed along a length direction of the base plate 171b1.
A terminal 171b3 configured to electrically connect the heating element 171b2 to power is provided at one side of the base plate 171b1, and a lead wire 173 electrically coupled to the power is provided to the terminal 171b3.
On the other hand, the heater case 171a is partitioned into an active heating part (AHP) corresponding to a portion on which the heating element 171b2 is disposed and a passive heating part (PHP) corresponding to a portion on which the heating element 171b2 is not disposed.
The active heating part (AHP) is a portion directly heated by the heating element 171b2, and working fluid (F) at the liquid phase is heated by the active heating part (AHP) and phase-changed into the gas phase at high temperatures.
The outlet 171c′, 171c″ of the heater case 171a may be located within the active heating part (AHP) or located at a front side than the active heating part (AHP). In
The passive heating part (PHP) is formed at a rear side of the active heating part (AHP). The passive heating part (PHP) indirectly receives heat to be heated to a predetermined temperature level though it is not a portion directly heated by the heating element 171b2 like the active heating part (AHP). Here, the passive heating part causes a predetermined temperature increase to the working fluid (F) in the liquid phase, but does not have high temperatures to the extent of phase-changing the working fluid (F) to the gas phase. In other words, in the aspect of temperature, the active heating part (AHP) forms a relatively high-temperature portion and the passive heating part forms a relatively low-temperature portion.
If working fluid (F) is configured to directly return to a side of the active heating part (AHP) at high temperatures, then it may occur a case where the collected working fluid (F) is reheated and flowed backward without being efficiently returned into the heater case 171a. It may be an obstacle to the circulation flow of the working fluid (F) within the heat pipe 172, thereby causing a problem of overheating the heater 171b.
In order to solve the foregoing problem, it is configured such that the inlet 171d′, 171d″ of the heating unit 171 is formed to correspond to the passive heating part (PHP) not to allow working fluid (F) that has moved through the heat pipe 172 and then returned to be immediately introduced into the active heating part (AHP).
According to the present embodiment, it is configured that the inlet 171d′, 171d″ of the heating unit 171 is located within the passive heating part (PHP) to allow working fluid (F) that has moved through the heat pipe 172 and then returned to be introduced into the passive heating part (PHP). In other words, the inlet 171d′, 171d″ of the heating unit 171 is formed at a portion on which the heating element 171b2 is not disposed on the heater case 171a.
As described above, the passive heating part (PHP) is associated with the formation location of the heating element 171b2. Accordingly, if the heating element 171b2 is not extended and formed up to the inlet 171d′, 171d″ of the heating unit 171, then the base plate 171b1 of the heater 171b may be extended and formed up to a portion corresponding to the inlet 171d′, 171d″. In other words, the base plate 171b1 may be disposed to cover the most bottom surface of the heater case 171a, and the heating element 171b2 may be formed at a position out of the inlet 171d′, 171d″, thereby preventing working fluid (F) returned through the inlet 171d′, 171d″ from flowing backward.
Hereinafter, the detailed structure of the heater case 171a and the coupling structure between the heater case 171a and the heater 171b will be described in more detail.
The heater case 171a may include a main case 171a1, a first cover 171a2 and a second cover 171a3 coupled to both sides of the main case 171a1, respectively.
The main case 171a1 is provided with a vacant space therein, and has a shape in which both end portions thereof are open. The main case 171a1 may be formed of an aluminum material. In
The first and the second cover 171a2, 171a3 are mounted at both sides of the main case 171a1 to cover both end portions of the main case 171a1 that are open. The first and the second cover 171a2, 171a3 may be formed of an aluminum material like the main case 171a1.
According to the present embodiment, it is shown a structure in which the outlet 171c′, 171c″ and the inlet 171d′, 171d″ are provided at positions separated from each other along a length direction of the main case 171a1, respectively, and the both end portions (the entrance portion 172c′, 172c″ coupled to the outlet 171c′, 171c″ and the return portion 172d′, 172d″ coupled to the inlet 171d′, 171d″) of the heat pipe 172 are coupled to the outlet 171c′, 171c″ and the inlet 171d′, 171d″.
More specifically, the first outlet 171c′ and the first inlet 171d′ are formed at positions separated from each other along a length direction on one lateral surface of the main case 171a1, and the second outlet 171c″ and the second inlet 171d″ are formed at positions separated from each other along a length direction on the other lateral surface facing the one surface. Here, the first outlet 171c′ and the second outlet 171c″ may be disposed to face each other, and the first inlet 171d′ and the second inlet 171d″ may be disposed to face each other.
However, the present disclosure may not be necessarily limited to this. At least one of the inlet 171d′, 171d″ and the outlet 171c′, 171c″ may be formed on a first and/or a second cover 171a2, 171a3.
On the other hand, the heating unit 171 is provided at the lower side of the evaporator 130, and thus defrost water generated due to defrosting in the aspect of the structure may flow down to the heating unit 171. The heater 171b provided in the heating unit 171 is an electronic component, and thus when defrost water is brought into contact with the heater 171b, it may cause a short circuit. As described above, the heating unit 171 of the present disclosure may include the following sealing structure to prevent moisture including defrost water from infiltrating into the heater 171b.
First, the heater 171b is attached to a bottom surface of the main case 171a1, and a first and a second extension fin 171a1a, 171a1b extended and formed in a downward direction from the bottom surface to cover a lateral surface of the heater 171b attached to the bottom surface are configured at both sides of the main case 171a1. Due to the structure, even when defrost water generated due to defrosting falls onto the main case 171a1 and flows down along an outer surface of the main case 171a1, the defrost water does not infiltrate into the heater 171b accommodated at an inner side of the first and the second extension fin 171a1a, 171a1b.
Furthermore, a sealing member 171e may be filled into a recessed space 171a1′ formed by a rear surface of the heater 171b and the first and the second extension fin 171a1a, 171a1b as described above. Silicon, urethane, epoxy or the like may be used for the sealing member 171e. For example, epoxy in the liquid phase may be filled into the recessed space 171a1′ and then subject to the curing process to complete the sealing structure of the heater 171b. Here, the first and the second extension fin 171a1a, 171a1b may function as a sidewall limiting the recessed space 171a1′ into which the sealing member 171e is filled.
An insulating material 171f may be interposed between a rear surface of the heater 171b and the sealing member 171e. A mica sheet with a mica material ma be used for the insulating material 171f. The insulating material 171f may be disposed on a rear surface of the heater 171b, thereby limiting heat from being transferred to a side of the rear surface of the heater 171b when the heating element 171b2 emits heat according to the application of power.
Moreover, a thermally conductive adhesive 171g may be interposed between the main case 171a1 and the heater 171b. The thermally conductive adhesive 171g may attach the heater 171b to the main case 171a1 to perform the role of transferring heat generated from the heater 171b to the main case 171a1. A heat-resistant silicone capable of enduring high temperatures may be used for the thermally conductive adhesive 171g.
On the other hand, at least one of the first and the second cover 171a2, 171a3 may be extended and formed from the bottom of the main case 171a1 in a downward direction to surround the heater 171b along with the first and the second extension fin 171a1a, 171a1b. Due to the structure, the filling of the sealing member 171e may be more easily carried out.
However, considering a structure in which the lead wire 173 coupled to the terminal 171b3 of the heater 171b is extended from one side of the heater case 171a to an outside, a cover corresponding to one side of the heater case 171a on the first and the second cover 171a2, 171a3 may not be extended and formed in a downward direction or may be provided with a groove or hole allowing the lead wire 173 to pass therethrough even when extended and formed in a downward direction.
According to the present embodiment, it is shown that the second cover 171a3 is extended and formed from the bottom surface of the main case 171a1 in a downward direction, and the lead wire 173 is extended and formed to a side of the first cover 171a2.
Considering a heating unit 271 in detail with reference to the accompanying drawings, the heating unit 271 may include a heater case 271a and a heater 271b.
According to the present embodiment, the heater case 271a is extended and formed along one direction and disposed in an elongated manner along a horizontal direction at a lower portion of the evaporator 130. The heater case 271a may be formed in a cylindrical or rectangular pillar shape, and formed of a copper material or aluminum material.
The heater case 271a may be disposed adjacent to the lowest column of the cooling tube 131. For example, the heater case 271a may be disposed at the same height as the lowest column of the cooling tube 131 or disposed at a position lower than the lowest column of the cooling tube 131.
The heater case 271a has a hollow shape therein, and is coupled to both end portions of the heat pipe 172, respectively, to form a closed loop shaped passage through which working fluid (F) can circulate along with the heat pipe 172. The first and the second outlet 271c′, 271c″ and the first and the second inlet 271d′, 271d″ coupled to both end portions of the first and the second heat pipe 172′, 172″, respectively, are formed at both sides of the heater case 171a, respectively, in a horizontal direction.
Specifically, the first and the second outlet 271c′, 271c″ communicated with one end portion of the first and the second heat pipe 172′, 172″, respectively, is formed at one side of the heater case 271a (for example, an outer circumferential surface adjacent to a front end portion of the heater case 271a). The first and the second inlet 271d′, 271d″ denote an opening through which working fluid (F) heated by the heater 271b is discharged to the first and the second heat pipe 172′, 172″.
The first and the second inlet 271d′, 271d″ communicated with the other end portion of the first and the second heat pipe 172′, 172″, respectively, is formed at the other side of the heater case 271a (for example, an outer circumferential surface adjacent to a rear end portion of the heater case 271a). The first and the second inlet 271d′, 271d″ denote an opening through which condensed working fluid (F) is collected to the heater case 271a while passing through the first and the second heat pipe 172′, 172″.
The heater 271b has a shape in which part thereof is accommodated into the heater case 271a and extended along a length direction of the heater case 271a. According to the present conceptual view, it is shown that the heater 271b is arranged in parallel along a horizontal direction of the evaporator 130.
The heater 271b may be inserted through the other side of the heater case 271a and fixed and sealed to the heater case 271a. Here, it is configured such that part of the heater 271b is accommodated into the heater case 271a, and another part of the heater 271b is exposed to an outside of the heater case 271a.
The heater 271b accommodated into the heater case 271a is disposed to be separated from an inner circumferential surface of the heater case 271a by a preset distance. According to the layout, an annular space having an annular gap is formed between an inner circumferential surface of the heater case 271a and an outer circumferential surface of the heater 271b.
A heating coil 271b1b (refer to
The first and the second heat pipe 172′, 172″ are coupled to the first and the second outlet 271c′, 271c″ provided at the left side of the heater case 271a on the drawing and the first and the second inlet 271d′, 271d″ provided at the right side thereof, respectively, and a predetermined amount of working fluid (F) is filled therein.
The first and the second heat pipe 172′, 172″ may be coupled to the first and the second outlet 271c′, 271c″ and the first and the second inlet 271d′, 271d″ of the heater case 271a, but when they are formed of different types of materials (as described above, when the first and the second heat pipe 172′, 172″ are formed of an aluminum material, and the heater case 271a is formed of a copper material), it may be difficult to perform a connection operation.
In this case, an outlet tube 271g′, 271g″ may be extended and formed on the first and the second outlet 271c′, 271c″, and a return tube 271h′, 271h″ may be extended and formed on the first and the second inlet 271d′, 271d″ to connect between the heater case 271a and the first and the second heat pipe 172′, 172″. The outlet tube 271g and the return tube 271h may be formed of the same material as that of the heater case 271a, and integrally coupled to each other. In this manner, it may be understood that the outlet tube 271g and the return tube 271h are an additional configuration between them for an easy connection to the first and the second heat pipe 172′, 172″.
As working fluid (F) filled therein by the heating unit 271 is heated to high temperatures, the working fluid (F) flows due to a pressure difference to move the first and the second heat pipe 172′, 172″. Specifically, the working fluid (F) at high temperatures heated by the heater 271b and discharged to the first and the second outlet 271c′, 271c″ transfers heat to the cooling tube 131 of the evaporator 130 while moving through the first and the second heat pipe 172′, 172″. The working fluid (F) is gradually cooled while passing through the heat exchange process and introduced into the first and the second inlet 271d′, 271d″. The cooled working fluid (F) is reheated by the heater 271b and then discharged to the outlet first and the second outlet 271c′, 271c″ again to repeatedly perform the foregoing processes. The defrosting of the cooling tube 131 is carried out due to such a circulation method.
On the other hand, a defrosting device 270 may be configured as follows to prevent the overheating of the heater 271b.
First, as described above, the heater 271b has a shape in which at least part thereof is accommodated into the heater case 271a and extended along a length direction of the heater case 271a. Furthermore, a predetermined amount of working fluid (F) is filled into the heating unit 271 and heat pipe 272.
When the heater 271b is operated in case where an upper end portion of the heater 271b is exposed above the water level of the working fluid (F) when the whole of working fluid (F) is placed in the liquid phase (when the heater 271b is not operated), the temperature of the upper end portion of the heater 271b abruptly increases, contrary to the remaining portion thereof immersed in the working fluid (F).
When such a state continues, the upper end portion of the heater 271b is overheated to cause a critical damage (for example, fire) on the defrosting device 270, and generate a phenomenon in which heated working fluid (F) flows backward to the other end portion of the heat pipe 272 through which the returned working fluid (F) flows.
In order to prevent such a phenomenon, working fluid (F) filled into the heater case 271a is filled in the liquid phase to form a water level at a position higher than that of the upper end portion of the heater 271b. In other words, it is configured such that the heater 271b is immersed below the water level of the working fluid (F).
According to the foregoing configuration, since the heater 271b is heated in a state of being immersed below the water level of the working fluid (F) in the liquid phase, the working fluid (F) evaporated by heating may be sequentially transferred to one end portion of the heat pipe 272, thereby allowing efficient circulation flow as well as preventing the overheating of the heating unit 271.
On the other hand, referring to
On the other hand, the heater 271b is divided into an active heating part 271b1 and a passive heating part according to whether or not the heater 271b emits heat in an active manner, and the passive heating part may include a first passive heating part 271b2 at a rear side of the active heating part 271b1 and a second passive heating part 271b3 at a front side of the active heating part 271b1.
Specifically, the active heating part 271b1 is configured to generate heat in an active manner. The working fluid (F) in the liquid phase may be heated by the active heating part 271b1 and phase-changed into the gas phase at high temperatures.
The first and the second outlet 271c′, 271c″ of the heater case 271a may be located to correspond to the active heating part 271b1 or located at a front side than the active heating part 271b1. In
Due to the foregoing structure, part of working fluid (F) stays at a front end portion (a space between an inner front end and the outlet 271c′, 271c″ of the heater case 271a) to prevent the overheating of the heater 271b.
Specifically, working fluid (F) heated by the active heating part 271b1 moves in a direction through which the working fluid (F) circulates, namely, toward a front end portion of the heater case 271a, and during this process, part of the working fluid (F) is discharged to the branched outlet 271c′, 271c″, but the remaining working fluid passes through the outlet 271c′, 271c″ and stays while forming a vortex at a front end portion of the heater case 271a.
The whole of the heated working fluid (F) is not immediately discharged to the outlet 271c′, 271c″, but part thereof stays within the heater case 271a to be brought into contact with the active heating part 271b1 without being immediately discharged to the outlet 271c′, 271c″, thereby further preventing the overheating of the active heating part 271b1.
The first passive heating part 271b2 is extended and formed in a backward direction at a rear end of the active heating part 271b1. The first passive heating part 271b2 receives heat by the active heating part 271b1 to be heated to a predetermined temperature level though it does not generate heat by itself like the active heating part 271b1. Here, the first passive heating part 271b2 causes a predetermined temperature increase to the working fluid (F) in the liquid phase, but does not have high temperatures to the extent of phase-changing the working fluid (F) to the gas phase.
Considering the heater 271b in the aspect of temperature, the active heating part 271b1 forms a relatively high-temperature portion and the first passive heating part 271b2 forms a relatively low-temperature portion.
Structurally, a heating coil 271b1b (refer to
If working fluid (F) is configured to directly return to a side of the active heating part 271b1 at high temperatures provided within the heating unit 271, then it may occur a case where the collected working fluid (F) is reheated and flowed backward without being efficiently returned into the heating unit 271. It may be an obstacle to the circulation flow of the working fluid (F) within the heat pipe 272, thereby causing a problem of overheating the heating unit 271.
In order to solve the foregoing problem, it is configured such that the inlet 271d′, 271d″ of the heating unit 271 is formed at a position out of the active heating part 271b1 not to allow working fluid (F) that has moved through the heat pipe 272 and then returned to be immediately introduced into the active heating part 271b1.
In association with this, according to the present embodiment, it is configured that the inlet 271d′, 271d″ of the heating unit 271 is located to correspond to the first passive heating part 271b2 to allow working fluid (F) that has moved through the heat pipe 272 and then returned to be introduced into a space between the heater case 271a and the first passive heating part 271b2. In other words, the inlet 271d′, 271d″ of the heating unit 271 is formed on an outer circumference of a portion surrounding the first passive heating part 271b2 on the heater case 171a.
Here, it is configured such that part of the first passive heating part 271b2 is exposed to an outside in a backward direction from a rear end portion of the heater case 271a. The first passive heating part 271b2 exposed to an outside of the heater case 271a is configured to emit the heat of the heater 271b to an outside to reduce a surface load density of the heater 271b. When the surface load density of the heater 271b is reduced, the overheating of the heater 271b may be prevented to secure reliability as well as extend the lifespan of the heater 271b.
Hereinafter, the external heat emission structure of the first passive heating part 271b2 and the sealing structure of the first passive heating part 271b2 exposed to an outside will be described in detail based on the detailed configuration of the heater 271b.
Referring to
The heater 271b is divided into an active heating part 271b1 and a passive heating part according to whether or not the heater 271b emits heat in an active manner, and the passive heating part may include a first passive heating part 271b2 at a rear side of the active heating part 271b1 and a second passive heating part 271b3 at a front side of the active heating part 271b1.
The active heating part 271b1 may include a bobbin 271b1a in a pillar shape inserted into the heater frame 271ba in a length direction, and a heating coil 271b1b wound on an outer circumference of the bobbin 271b1a and extended along the length direction of the bobbin 271b1a. The bobbin 271b1a may be formed of an insulating material, for example, magnesium oxide. It is configured that the heating coil 271b1b is heated to high temperatures when power is supplied through the lead wire 271b1c which will be described later. A nichrome wire may be used for the heating coil 271b1b.
The first and the second passive heating part 271b2, 271b3 may include insulating materials 271b2a, 272b3a filled into an inner vacant space at a rear side and a front side of the heater frame 271ba into which the bobbin 271b1a is inserted, respectively. For an example, magnesium oxide powder which is an insulating material 271b2a may be sealed into an inner vacant space at a rear side of the heater frame 271ba into which the bobbin 271b1a is inserted and then internal air may be discharged to form a solidified first passive heating part 271b2.
The insulating materials 271b2a, 272b3a may be filled into a vacant space between an outer circumference of the bobbin 271b1a and an inner circumference of the heater frame 271ba. In other words, a drawing in which the insulating materials 271b2a, 272b3a are provided at a front side and a rear side of the bobbin 271b1a, respectively, is only a conceptual division for the sake of convenience of explanation, and it does not mean that they are completed divided.
The lead wire 271b1c is configured to connect the power to the heating coil 271b1b through the insulating material 271b2a forming the first passive heating part 271b2. The lead wire 271b1c may be configured to pass through the bobbin 271b1a.
A cover member 271bb may be coupled to a front opening portion of the heater frame 271ba to cover the insulating material 272b3a forming the second passive heating part 271b3. The cover member 271bb may be coupled to the heater frame 271ba by welding, and have an inwardly concave shape to endure a pressure occurring within the heater 271b. According to the foregoing structure, a front end of the second passive heating part 271b3 constitutes a front end of the heater 271b.
On the other hand, the heater frame 271ba may be fixed to the heater case 271a through a fastening member 271e. The fastening member 271e is formed to surround an outer circumference of the heater frame 271ba, and fastened to the heater case 271a. A space between the heater frame 271ba and the fastening member 271e and between the fastening member 271e and the heater case 271a may be sealed to prevent the introduction of air or moisture. To this end, the fastening member 271e may be configured to include an elastic material so as to be closely coupled to the heater frame 271ba and heater case 271a or sealed by a heat-resistant silicone, welding or the like.
A rear end portion of the heater case 271a and the heater frame 271ba exposed to an outside may be wrapped and sealed by heat shrink tube 271f. The heat shrink tube 271f is shrunk during heating to be closed adhered to the components accommodated therein, thereby closely sealing a gap between the heater case 271a and the heater frame 271ba. The heat shrink tube 271f may be configured to wrap and seal even part of the lead wire 271b1c extended from the heater frame 271ba to an outside.
The first and the second inlet 271d′, 271d″ of the heater case 271a may be formed at a position separated from a rear end of the heater case 271a by a predetermined distance in an inward direction to form the fixing and sealing structure of the foregoing heater 271b at a rear end portion of the heater case 271a.
According to the present example, a total number of columns of the first heat pipe 372′ disposed on a front portion of the evaporator 330 may be configured to be less than that of the second heat pipe 372″. Here, the total number of columns denotes a total number of columns formed by a plurality of horizontal tubes 372b1 on a heat emitting part 372b constituting a heat pipe 372.
According to the foregoing structure, a path through which working fluid (F) circulates may be shorter to allow the temperature of the first and the second heat pipe 372′, 372″ to increase as a whole, and a total number of columns of the second heat pipe 372″ may be larger than that of the first heat pipe 372′ to transfer more heat to the second heat pipe 372″.
On the present drawing, it is shown that the first heat pipe 372′ is configured with total six columns and the second heat pipe 372″ is configured with total eight columns. Specifically, in a state that the highest and the lowest column of the second heat pipe 372″ are disposed to correspond to the highest and the lowest column of the first heat pipe 372′, respectively, a distance between two columns adjacent to each other on the first heat pipe 372′ is disposed to be larger than that between two columns adjacent to each other on the second heat pipe 372″.
The adjoining two columns of the first heat pipe 372′ may be provided at an upper portion of the first heat pipe 372′. According to the foregoing structure, a distance between the adjoining two columns at a lower portion of the first heat pipe 372′ may be configured to be less than that at the upper portion.
It is a design considering convection according to the temperature of working fluid (F) when the working fluid circulates through the first heat pipe 372′. According to the foregoing structure, even when it is configured that a number of columns of the first heat pipe 372′ is less than that of the second heat pipe 372″, defrosting on a front portion of the evaporator 330 may be efficiently carried out by the effective layout of the first heat pipe 372′.
On the other hand, the present disclosure may not be necessarily limited to this. The highest column of the first heat pipe 172′ may be disposed to be lower than the highest column of the second heat pipe 172″ or the lowest column of the first heat pipe 172′ may be disposed to be higher than the lowest column of the second heat pipe 172″. In this case, a distance between two columns adjacent to each other on the first heat pipe 171′ may be formed to correspond to (to be the same or similar to) that between two columns adjacent to each other on the second heat pipe 172″.
Number | Date | Country | Kind |
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10-2015-0158325 | Nov 2015 | KR | national |