KR101091007B1 - Duct of indirect type refrigerator - Google Patents

Abstract

The present invention relates to a duct for an intercooled refrigerator, and in particular, includes a duct panel, the discharge port is formed in the duct panel, the discharge port includes a first discharge port and a second discharge port disposed below the first discharge port. The flow path cross-sectional area of the first discharge port is larger than the flow path cross-sectional area of the second discharge port, so that more cold air is discharged to the discharge port formed at the upper portion than the lower portion where cold air is collected, thereby maintaining the temperature of all parts uniformly. The present invention relates to a duct for an intercooled refrigerator that can accurately detect a temperature when a sensor senses a temperature inside a refrigerator, thereby increasing energy efficiency.

Intercooled, Refrigerated, Duct

Description

Duct for indirect type refrigerator

The present invention relates to a duct for an intercooled refrigerator, and in particular, includes a duct panel, the discharge port is formed in the duct panel, the discharge port includes a first discharge port and a second discharge port disposed below the first discharge port. In addition, the flow path cross-sectional area of the first discharge port relates to a duct for a cold-cooled refrigerator formed larger than the flow path cross-sectional area of the second discharge port.

In general, in the intercooled refrigerator having a freezer compartment fan and a refrigerating compartment fan separately installed above the cooler, the cold air supply of the freezer compartment sucks cold air from the cooler (not shown) side where the freezer compartment fan is located as shown in FIG. 1. It is made by discharging to the front freezer compartment 20, but the cold air supply of the refrigerating compartment 30 is located in the lower side of the refrigerating compartment 30, so the cold air discharged forward by the refrigerating compartment fan 31 to the freezer compartment louver insulator 25 After hitting the U-turn, it enters the upper opening of the refrigerating compartment cold air duct 10 installed between the inner box and the cabinet behind the cooler, is guided downward along the refrigerating compartment cold air duct, and flows into the refrigerating compartment multi duct 40 so as to enter the refrigerating compartment multi duct 40. It is to be supplied into the refrigerating chamber 30 through the cold air discharge port.

The refrigerating compartment cold air duct 10 as described above is an insulating material 11 for insulating the cold air passage in a portion of the panel-shaped refrigerating compartment cold air duct 10 in which a cold air passage is formed from the rear of the freezing compartment 20 to the upper side of the refrigerating compartment 30. ) And its lower cover.

The conventional refrigerator has a problem that the size of the discharge holes in the upper part and the lower part is formed the same so that the temperature inside the refrigerator cannot be maintained uniformly.

The present invention has been made to solve the above-described problem, to provide a cold-cooled duct that can maintain a uniform temperature of all parts by discharging more cold air to the discharge port formed in the upper portion than the lower cold air collecting its purpose There is this.

The duct for the cold-cooled refrigerator of the present invention for achieving the above object includes a duct panel, the discharge port is formed in the duct panel, the discharge port is the first discharge port and the second discharge port disposed below the first discharge port It includes, wherein the flow path cross-sectional area of the first discharge port is formed larger than the flow path cross-sectional area of the second discharge port.

In the above-described configuration, the discharge port is formed on both sides of the duct panel, the discharge port is formed long up and down, the bent portion is formed in the duct panel, the bent portion is bent toward the front to the height toward the inside Is formed to be inclined to be lower, the bent portion is formed in the bent portion, the depression is formed to be inclined so that the depth is lower toward the inside, the discharge port may be formed in the depression.

According to the duct for the intercooled refrigerator of the present invention as described above, there are the following effects.

And a duct panel, wherein a discharge port is formed in the duct panel, and the discharge port includes a first discharge port and a second discharge port disposed below the first discharge port, and a passage cross-sectional area of the first discharge port is the second discharge port. It is formed larger than the cross-sectional area of the flow path, so the cold air is discharged to the upper part of the upper part rather than the lower part where cold air is collected, so that the temperature of all parts can be maintained uniformly. Sensing can increase energy efficiency.

The discharge holes are formed on both sides of the duct panel, respectively, and the discharge holes are formed to extend up and down, thereby effectively transferring cold air to the middle portion of the storage compartment of the case.

A bent portion is formed in the duct panel, and the bent portion is bent forward to be inwardly formed to be inclined so as to have a lower height, and the bent portion is formed to be inclined, and the depressed portion is inwardly so as to have a lower depth. It is formed to be inclined, the discharge port is formed in the depression, so that the cross-sectional area of the flow path is wider toward the outside of the duct panel, the temperature inside the storage compartment of the in-case can be kept uniform.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

For reference, among the configurations of the present invention to be described below, the same configuration as the prior art will be referred to the above-described prior art, and a detailed description thereof will be omitted.

Figure 2 is a perspective view before installation of the duct assembly for a cold-cooled refrigerator according to a preferred embodiment of the present invention, Figure 3 is an exploded perspective view of the duct assembly for the cold-cooled refrigerator of Figure 2, Figure 4 is a front view of the duct assembly for the cold-cooled refrigerator of Figure 2, 5 is a perspective view of the duct assembly for the intercooled refrigerator of FIG. 2, FIG. 6 is a rear perspective view of the duct assembly for the intercooled refrigerator of FIG. 2, FIG. 7 is a rear view of the duct assembly for the intercooled refrigerator of FIG. 2, and FIG. 8 is a view of FIG. 4. It is AA sectional drawing, FIG. 9 is a rear perspective view of the duct assembly for the intercooled refrigerator of FIG.

2 to 9, the duct assembly installation structure for the intercooled refrigerator of the present embodiment includes an incase 100 in which the storage compartment 101 is formed and a duct assembly 200 installed in the storage compartment 101. The duct assembly 200 includes a duct, a sensor 230 installed in the duct, sensing a temperature, and a lamp 240 installed in the duct.

The incase 100 has a side surface 130 connected to both sides of the top surface 120 and the top surface 120, and a bottom surface 150 connected to the bottom of both side surfaces 130, and an upper surface 120 and a side surface 130. ), A front surface 110 connected to the front of the bottom surface 150, and the top surface 120, the side surface 130, a rear surface (not shown) connected to the rear of the bottom surface 150. As a result, the storage case 101 having the front open is formed in the incase 100.

The incase 100 is formed of a synthetic resin material such as PVC.

A plurality of long grooves are formed on the inner wall of the bottom surface 150 and the top surface 120. As described above, even when the food is in contact with the bottom surface 150 or the top surface 120, the cold air stays in the groove to effectively cool the food. In addition, the rigidity of the incase 100 formed of a synthetic resin material may be further improved.

Protruding inward to the side surface 130, the locking projection 132 is formed in the front and rear directions. The locking protrusion 132 is formed by making fun of the inside of the side surface 130, whereby the groove 131 is formed on the outside of the side surface 130. A shelf (not shown) is disposed on the locking protrusion 132.

The rear and side surfaces 130 of the incase 100 are provided with mounting grooves (not shown) in which the duct assembly 200 and the heat exchanger may be mounted.

In addition, fitting grooves (not shown) are formed at the rear and side surfaces 130 of the incase 1100.

The duct assembly 200 is installed at the rear side of the storage compartment 101.

The duct assembly 200 includes the duct, a metal plate 280 disposed behind the duct, an insulation 270 installed in the duct, and a sensor 230 installed in the duct to sense a temperature. ) And a lamp 240 installed in the duct.

The duct includes a duct panel 210 disposed at the front and a rear portion disposed at the rear of the duct panel 210. The duct is formed of a synthetic resin material such as PVC.

As such, the duct and the incase 100 are formed of a synthetic resin, thereby reducing the weight of the refrigerator and reducing the production cost by reducing the material cost.

The duct panel 210 is provided as one plate, and is bent forward to the upper portion and then bent to the upper portion to form a protruding protrusion 219.

The front surface of the protrusion 219 is formed with a deodorization insertion unit 212a in which the deodorant 252 is inserted in the middle portion. In addition, the through hole is formed in the front-rear direction in the deodorization insertion unit 212a. Furthermore, a fastening protrusion protrudes from the front surface of the protrusion 219 so as to be disposed around the deodorization insertion unit 212a.

As such, the deodorant assembly 250 including the deodorant 252 and the deodorant cover 251 is installed in the duct. The deodorant 252 includes a housing in which a through hole into which a deodorant and a deodorant is inserted is formed. When assembling, the through hole formed in the housing of the deodorant 252 is in communication with the through hole formed in the deodorization insertion unit 212a. The deodorant cover 251 is formed through the ventilation hole, and is installed to be detachable from the protrusion 219 through a fastening protrusion formed in the protrusion 219.

The lamp insertion part 212c into which the lamp 240 is inserted is formed at the lower front corner portion of the protrusion 219. In addition, the protrusion 219 is formed with a drawing hole through which the electric wire is drawn out so as to communicate with the lamp insertion portion 212c.

The rear surface of the protrusion 219 is formed such that the sensor insertion portion 212b into which the sensor 230 is inserted is protruded forward to be disposed above the deodorization insertion portion 212a. The protrusion 219 is provided with a vent so as to communicate with the sensor inserting portion 212b.

On the upper and side edges of the duct panel 210, a plurality of hooks 211 fitted into the fitting grooves formed in the incase 100 are formed along the circumference of the duct panel 210.

In addition, the duct panel 210 has bent portions 218 formed at both sides of the lower portion of the protrusion 219. The bent portion 218 is bent toward the front side is formed to be inclined so that the height is lower toward the inside. For this reason, the cross-sectional area of the flow path becomes wider as it faces toward the outside of the duct panel 210. Therefore, the temperature of all parts of the storage compartment 101 of the incase 100 may be maintained uniformly.

The bent portion 218 is formed with a depression 217, the depression 217 is formed to be inclined so that the depth is lower toward the inside. Thus, the depression 217 is formed, so that the bottom surface of the depression 217 is vertical. A plurality of recesses 217 are formed and arranged along the vertical direction.

The duct panel 210 has fastening holes 216 disposed on both sides of the bent portion 218 at the bottom of the protrusion 219, and are fastened to be disposed on the lower portion of the bent portion 218. 216 are formed on both sides.

The duct panel 210 is integrally formed with a discharge port through which cold air is discharged and a suction port 215 through which air is sucked.

The discharge port includes an upper discharge port 213 disposed on the upper portion of the duct panel 210 and side discharge holes 214 disposed on both sides of the duct panel 210.

The upper discharge port 213 is formed in a long hole shape and arranged horizontally, a plurality is provided is arranged along the vertical direction. In addition, the upper discharge port 213 is disposed on both sides of the deodorizing assembly 250, respectively.

The side discharge port 214 is formed in the depression 217, it is formed long up and down. A plurality of the side discharge port 214 is also provided is arranged along the width direction of the duct panel 210. Thus, the side discharge port 214 is provided, it is possible to effectively transmit the cold air to the middle portion of the storage compartment 101 of the in-case 100.

In addition, the side discharge port 214 includes a first discharge port 214a and a second discharge port 214b disposed below the first discharge port 214a, and the flow path cross-sectional area of the first discharge port 214a is the first discharge port 214a. It is formed larger than the flow path cross-sectional area of the two discharge ports 214b. In the present embodiment, a third discharge port 214c may be further formed below the second discharge port 214b. Therefore, the flow path cross-sectional area becomes larger from the first discharge port 214a toward the third discharge port 214c.

The first discharge port 214a is formed longer in the vertical direction than the second discharge port 214b, so that the flow path cross section is larger.

As such, the flow path area of the side discharge port 214 is formed differently, so that more cold air is discharged to the discharge hole formed in the upper portion than the lower portion where the cold air is collected a lot, and thus the temperature of all parts can be maintained uniformly. When sensing the temperature inside, the temperature can be detected accurately, which can increase energy efficiency.

The inlet 215 is disposed under the duct panel 210 to be disposed below the outlet, so that cold air descending downwardly cools the inside of the storage compartment 101 of the incase 100 and the inlet 215. Through the suction effectively. This allows the cold air to be effectively circulated.

The support piece 218a is formed to protrude from the rear surface of the duct panel 210 so as to be disposed at both sides of the bent portion 218. The support piece 218a is formed to protrude along the vertical direction and the horizontal direction.

The rear part includes a first rear panel 260, a second rear panel 220 installed on a rear surface of the first rear panel 260, and a discharge channel 290 provided on a rear surface of the bent portion 218.

The first rear panel 260 includes a first surface 266 disposed at the rear of the protrusion 219 and a second surface 267 disposed at both rear sides of the first surface 266, so that the protrusion 219 is disposed. It is installed on the back of the. The first rear panel 260 serves to organize the wires connected to the sensor 230 and the lamp 240 and protects the lamp 240 and the sensor 230 from the heat exchanger, thereby damaging them due to too low a temperature. Prevent it.

Inserting grooves 261, 262, and 264 into which the deodorizing inserting portion 212a, the lamp inserting portion 212c, and the sensor inserting portion 212b are inserted into the front surface of the first surface 266. Is formed.

In addition, a communication groove 268 communicating with three insertion grooves 261, 262, and 264 is formed on the front surface of the first surface 266 along the vertical direction. Due to the communication groove 268, the wires connected to the lamp 240 and the sensor 230 can be easily arranged.

The vent hole 262a is formed through the first surface 266 so as to communicate with the insertion groove 262.

The first surface 266 is formed through the vent hole 263 communicated with the upper discharge port 213 at the time of assembly.

Further, a through hole 265 through which the fastening protrusion 227 penetrates is formed in the first surface 266.

The second surface 267 is formed such that the top thereof is bent inward.

The second rear panel 220 includes the duct rear surface 224 and the duct side surfaces 225 formed on both sides of the rear side of the duct rear surface 224. It is placed between the rear.

The front of the duct rear surface 224 is formed so that the fastening protrusion 227 through which the bolt (B) penetrates. Due to the fastening protrusion 227, the first rear panel 260, the second rear panel 220, and the duct panel 210 are coupled to each other.

Through holes 222 are formed in the front and rear directions of the duct rear surface 224. In addition, a support frame 226 supporting the blowing fan F is radially formed at the rear of the duct rear surface 224 so that the blowing fan F is disposed in the through hole 222.

Fastening portions 223 protrude from the lower sides of the duct rear surface 224. The fastening hole formed in the fastening part 223 is formed to communicate with the fastening hole 216 of the duct panel 210. The bolts are fastened to the fastening holes of the fastening hole 216 and the fastening part 223, thereby coupling the second rear panel 220 and the duct panel 210 and simultaneously enclosing the duct assembly 200. Can be installed on

Further, the guide plate 221 protrudes from the rear side of the duct rear surface 224 so as to surround the through hole 222 and is formed in an arc shape. In detail, the guide plate 211 is formed in a “∩” shape so that the space between both sides of the guide plate 221 is wider as it goes downward. The lower portion of the guide plate 221 is formed to be bent to the outside and continues to the lower portion of the fastening portion 223 is connected to the lower side of the duct side (225). In addition, a plurality of ribs connecting the guide plate 211 and the duct rear surface 224 are formed. Due to the guide plate 221, the air sucked from the lower inlet 215 is effectively guided to the blowing fan F, and when the condensed water is generated, the condensed water does not fall to the blowing fan F and flows to both sides to be drained. Can be.

In addition, the sliding pieces 228 are formed to protrude on both inner sides of the guide plate 221. The sliding piece 228 is formed to be inclined. As such, the sliding piece 228 is provided to guide the condensate flowing along the inner wall of the guide plate 221 to the plate 280, thereby effectively preventing the drop.

During assembly, the duct side surface 225 is disposed inside the second surface 267 and faces the second surface 267.

The discharge channel 290 includes both side surfaces, a bottom surface, and a rear surface, and is formed to open at the front and the top thereof. Therefore, the flow path 291 formed in the discharge channel 290 at the time of assembling the discharge channel 290 communicates with the upper discharge port 213 and the side discharge port 214.

Grooves 292 are formed in front of both side surfaces of the discharge channel 290 so that they do not interfere with the recess 217 when assembled.

Both sides of the discharge channel 290 are supported by the support pieces 218a arranged vertically, and the bottom surface of the discharge channel 290 is supported by the support pieces 218a arranged horizontally, so that the discharge channels 290 are provided. Is disposed on the rear surface of the bent portion 218 of the duct panel 210.

The insulation 270 is disposed below the second rear panel 220 and is installed at the rear of the duct panel 210. In addition, the insulation 270 is disposed at the front of the heat exchanger during assembly to protect the heat exchanger and the duct.

Insulation 270 is formed such that the width of the upper portion 271 toward the upper portion becomes narrower. In detail, the upper portion 271 of the insulation 270 is formed in an arc shape, so that the width thereof becomes narrower toward the upper portion. As such, the insulation 270 is formed, so that the area of the insulation 270 can be maximized to maximize the protection role of the duct and the heat exchanger, and the condensate flows along the inclined surface of the upper part 271, thereby discharging the condensate. You can also do it smoothly.

In addition, the insulation 270 is disposed below the blower fan F to prevent the buildup of the blower fan F and the lower part of the blower fan F so that the blower fan F operates when the blower fan F is operated. It is possible to prevent noise from interfering with this enemy. In addition, it is possible to prevent the blower fan F from being damaged.

The plate 280 is installed at the rear upper portion of the insulation 270, and is disposed in front of the heat exchanger during assembly. Plate 280 and the insulation 270 is formed through the fastening hole through which the bolt can be fastened, it can be fixed to the back surface of the duct panel 210. Due to the plate 280, when condensate is generated in the duct, heat is transferred to the defrost heater of the heat exchanger, thereby preventing condensate dropping.

Plate 280 is formed of an aluminum material, it is provided with a rectangular plate. The upper portion of the plate 280 is bent to form a support portion 281. The support part 281 is installed at the rear of the protrusion 219 is disposed below the blowing fan (F). In addition, the support part 281 is arrange | positioned between the sliding pieces 228 of both sides. In this way, the supporting portion 281 is provided so that a large area is disposed below the blowing fan (F), it can be more effective to drop the lower portion of the blowing fan (F).

The sensor 230 is inserted into the sensor insertion unit 212b and installed at the protrusion 219 of the duct panel 210. In addition, the rear of the sensor 230 is supported by the first rear panel 260. The sensor 230 is disposed above the upper discharge port 213 to detect the temperature of the storage compartment 101. In this way, the sensor 230 is disposed on the upper portion of the discharge port which has the least impact on the cold air descending, it is possible to accurately measure the temperature inside the storage chamber 101 of the case (100).

The lamp 240 is installed at the protrusion 219 of the duct panel 210 to be disposed below the deodorizing assembly 250. In detail, the lamp 240 is inserted into the lamp insertion portion 212c formed at the lower front edge of the protrusion 219 to illuminate the front and the bottom of the storage compartment 101 as shown in FIG. 2. In addition, the lamp 240 is protected by a lamp cover 241 detachably installed in front of the duct panel 210. In this way, the lamp 240 may be installed to illuminate the front and the lower part, thereby effectively illuminating the inside of the storage compartment 101. The lamp 240 is turned on / off as the door is opened and closed to illuminate the inside of the storage compartment 101.

As such, the duct assembly 200 is modularized and installed in the incase 100. As a result of the modularization, the module is modularized into a single component and mounted on the vehicle body, thereby eliminating a separate assembly process, thereby simplifying the manufacturing process and improving assembly. Therefore, the number of parts is reduced and the manufacturing cost is reduced, thereby improving productivity. In addition, as the sensor 230 and the duct and the lamp 240 are modularized into one component, quality management can be made consistently, thereby facilitating parts management. In addition, the lines and circuit diagrams of the lamp 240 and the sensor 230 can be simply configured.

The operation of this embodiment having the above-described configuration will be described below.

After installing the insulation 270 behind the duct panel 210, the duct assembly 200 installs the plate 280 and installs the discharge channel 290 to be supported by the support piece 218a. Subsequently, after the first rear panel 260 is disposed behind the protrusion 219, the second rear panel 220 is disposed behind the first rear panel 260, and the bolt B is fastened to the fastening protrusion 227. The duct panel 210 and the first rear panel 260 and the second rear panel 220 are coupled to each other.

In addition, a heat exchanger is installed in the seating groove formed in the incase 100.

When the duct assembly 200 is pushed so as to be seated in the seating groove formed in the incase 100 in which the heat exchanger is installed, the hook 211 is fitted into the fitting groove formed in the incase 100 to the duct assembly 200. Assembly of the incase 100 is completed. In this way, the assembly of the duct assembly 200 and the incase 100 is possible with one touch.

In addition, the bolts are inserted into the four fastening holes 216 to more firmly fix the duct assembly 200 to the incase 100.

The assembled duct assembly 200 is discharged from the cold air of the heat exchanger to the upper discharge port 213 and the side discharge port 214 through the blowing fan (F). The discharged cold air cools down the storage compartment 101 and then descends and is sucked into the inlet 215, cooled by the heat exchanger, and then raised through the blower fan F to be discharged to the upper outlet 213 and the side outlet 214. do. As such, the cold air is circulated to effectively cool the storage compartment 101.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications or variations of the present invention without departing from the spirit and scope of the invention described in the claims below Can be carried out.

As described above, the duct for the intercooled refrigerator according to the present invention, in particular, can be applied to the composite standing kimchi refrigerator to cool the lower storage compartment by direct cooling and the upper storage compartment by intercooling.

1 is a cross-sectional view of a conventional refrigerator.

Figure 2 is a perspective view before installation of the duct assembly for an intercooled refrigerator according to a preferred embodiment of the present invention.

Figure 3 is an exploded perspective view of the duct assembly for the intercooled refrigerator of Figure 2;

4 is a front view of the duct assembly for the intercooled refrigerator of FIG.

Figure 5 is a perspective view of the duct assembly for the intercooled refrigerator of Figure 2;

FIG. 6 is a rear perspective view of the duct assembly for the intercooled refrigerator of FIG. 2; FIG.

Figure 7 is a rear view of the duct assembly for the intercooled refrigerator of Figure 2;

8 is a cross-sectional view taken along the line A-A of FIG.

Figure 9 is a perspective view of the rear side duct assembly for the cold cooling refrigerator of Figure 2;

** Description of symbols for the main parts of the drawing **

100: incase 101: storage room

110: front 120: top

130: side 131: groove

132: locking projection 150: the bottom surface

200: duct assembly 210: duct panel

211: hook

213: top discharge outlet 214: side discharge outlet

214a: first discharge outlet 214a: second discharge outlet

214c: third discharge port 215: suction port

216: fastening hole 217: depression

218: bent portion 219: protrusion

220: rear panel 221: guide plate

230: sensor 240: lamp

Claims (3)

delete delete A duct panel and a rear part disposed behind the duct panel, A discharge port is formed in the duct panel, The discharge port includes a first discharge port and a second discharge port disposed below the first discharge port, The flow path cross sectional area of the first discharge port is larger than the flow path cross sectional area of the second discharge port, The duct panel is formed with a bent portion, the bent portion is bent to the front is formed to be inclined so that the height is lower toward the inside, The bent portion is formed with a depression, the depression is formed to be inclined so that the depth is lower toward the inside, The discharge port is formed in the depression, The rear portion includes a first rear panel, a second rear panel installed on the rear surface of the first rear panel and a discharge channel provided on the rear surface of the bent portion, A plurality of insertion grooves are formed on the front surface of the first rear panel, the duct for the cold-cooled refrigerator is formed with a communication groove communicating with the insertion groove.

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