KR101260522B1 - Ice-making means for refrigerator - Google Patents

Abstract

The present invention relates to a deicing means of a refrigerator having a structure for rotating a plurality of ice trays to a single ice lever.

The ice making means of the refrigerator according to the present invention includes an ice making chamber 220 which is provided on the rear surface of the freezing chamber door 100 and generates ice; A water tank 210 provided above the ice making chamber 220 and supplying water to the ice making chamber 220; It is provided below the ice-making chamber 220, and has a configuration including an ice bank (230) for storing the ice generated in the ice-making chamber (220); The ice making chamber 220 includes an ice tray 224 in which water freezes, tray gears 310 and 312 provided on one side of the ice tray 224, and an ice ice that transmits rotational power to the tray gears 310 and 312. The lever 240, and the return member 340 to apply a rotational force to one side so that the ice tray 224 is in place. According to the present invention having such a configuration, there is an advantage that the separation of ice is smooth.

Refrigerator, De-icing, Ice Bank, Home Bar Door, Ice Lever, Pulley

Description

Ice-making means for refrigerator

1 is a front view showing the appearance of a refrigerator according to the prior art.

Figure 2 is a use state showing the internal structure of the freezer compartment of the refrigerator according to the prior art.

3 is a front perspective view of a freezer compartment in which a preferred embodiment of the refrigerator ice making means according to the present invention is installed;

Figure 4 is a rear perspective view of the freezer door showing a state of installation of a preferred embodiment of the refrigerator ice making means according to the present invention.

Figure 5 is a side cross-sectional view showing an installation state of a preferred embodiment of the refrigerator ice making means according to the present invention.

Figure 6a is an exploded perspective view showing the configuration of the home bar door and the ice bank constituting an embodiment of the present invention.

Figure 6b is a side cross-sectional view showing the installation state of the home bar door and the ice bank constituting an embodiment of the present invention.

Figure 7 is a partial side perspective view showing the installation state of the bank support plate and the movement guide constituting an embodiment of the present invention.

Figure 8 is a partial front perspective view showing the installation state of the bank support plate and the movement guide constituting an embodiment of the present invention.

9 is a rear perspective view showing a detailed configuration of an ice making chamber constituting an embodiment of the present invention.

Figure 10 is a partial perspective view showing the interior of the ice making chamber constituting the embodiment of the present invention.

11 is a side view showing the configuration of an ice tray constituting an embodiment of the present invention.

12 is a use state showing the open state of the home bar door constituting the embodiment of the present invention.

Figure 13 is a use state showing the rotation direction of each gear during the operation of the ice lever constituting an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100. Freezer door 110. Home panel

120. Home bar door 122. Door hinge

124. Hook Hook 126. Hook Fixture

200. Ice making means 202. Ice making case

210. Bucket 212. Lever

220. Ice making room 222. Interference lever

224.Istray 230.Icebank

232. Fixed protrusions 234. Front handle

236. Rear handle 240. Ice lever

250. Bank support plate 256. Moving roller

258. Fixing groove 260. Link

280. Moving Guide 300. Tray Case

310. Rewords 312.

314. Connecting Gear 320. Tray Body

322. Tray cover 324. Cover hinge

326. Tray rotation shaft 328. Rotation guide protrusion

330. Supporting projections 335. Rotating guide groove

337. Cover stopper 340. Returning member

The present invention relates to a refrigerator, and more particularly, to an ice making means of a refrigerator having a structure in which a plurality of ice trays are rotated with one ice lever.

In general, a refrigerator is a device for low-temperature storage of food, and stored in a refrigerator or refrigerated according to the state of the food to be stored.

The cold air supplied to the inside of the refrigerator is generated by the heat exchange action of the refrigerant, is continuously supplied into the refrigerator while repeatedly performing a cycle of compression, condensation, expansion, and evaporation, and the supplied refrigerant is supplied by convection. It is evenly distributed inside the refrigerator to store food in the refrigerator at a desired temperature.

1 and 2 are perspective views illustrating an example of an exterior of a conventional double door refrigerator and an interior of a freezer compartment.

As shown in these figures, a refrigerator compartment is provided on the inside right side of the refrigerator body, and a freezer compartment is provided on the left side. The refrigerating compartment and the freezing compartment are selectively opened and closed by the refrigerating compartment door 10 and the freezing compartment door 12, respectively.

In addition, a front surface of the freezer door 12 is provided with a dispenser 14 which can directly obtain ice and water stored in the refrigerator from the outside.

Meanwhile, an ice maker 20 for generating ice is provided at an upper end of the freezer compartment, and an ice bank 22 for storing ice generated in the ice maker 20 is installed below the ice maker 20.

An ice chute 24 for guiding the ice stored in the ice bank 22 is formed at the rear side of the freezing chamber door 12. Therefore, the ice stored in the ice bank 22 is guided to the dispenser 14 through the ice chute 24 and is taken out.

However, the above conventional technologies have the following problems.

In the prior art as described above, the operation of separating the ice produced by the ice maker 20 to the ice bank 22 generally uses an ice motor (not shown). In other words, the ice maker 20 is physically twisted by the ice motor to separate the ice.

Therefore, in this case, it is difficult for the user to confirm the separation state of the ice, and there are cases where ice chips remain or the ice is not separated in the portion where the torsion force is not sufficiently applied.

When the water is resupplied in the state that the ice pieces that are not iced remain in the ice making case, the water overflows the ice making machine 20 to fix the driving part of the ice making machine 20. There is a problem that is damaged.

An object of the present invention is to solve the problems of the prior art as described above, to provide an ice making means of a refrigerator provided with a single ice lever for rotating a plurality of ice trays at the same time.

Ice making means of the refrigerator according to the present invention for achieving the above object is provided on the rear surface of the freezer door, the ice making room for generating ice; A water tank provided at an upper side of the ice making chamber to supply water to the ice making chamber; It is provided below the ice-making chamber, and has a configuration including an ice bank for storing the ice generated in the ice-making chamber; The ice making chamber includes an ice tray for freezing water, a tray gear provided on one side of the ice tray, an ice lever for transmitting rotational power to the tray gear, and a return member for applying rotation force to one side so that the ice tray is in the original position. Characterized in that it comprises a.

The ice lever is characterized by surrounding the outside of the ice making chamber.

The moving lever is formed in a 'c' shape, and an end thereof is fixedly fastened to the tray gear.

The ice tray and the tray gear are provided in plural, and each ice tray and the tray gear are rotated by the same rotation shaft.

A connection gear for connecting each tray gear is further provided between the plurality of tray gears, and the moving lever is connected to any one of the plurality of tray gears.

Gears corresponding to each other are formed on the outer circumferential surfaces of the plurality of tray gears and the connection gears, and are gear-coupled to each other.

The present invention also provides a plurality of ice trays freeze water; A moving motion driving mechanism connected to at least one of the plurality of ice trays and disposed on an axis of rotation of the ice trays to provide rotational force; A plurality of tray gears connected to the plurality of ice tray rotation shafts, respectively, to transfer the rotational force generated by the driving mechanism to the plurality of ice trays; And a coupling gear provided between the plurality of tray gears and transferring the tray gear rotational movement of one side to another tray gear.

According to the present invention having such a configuration, there is an advantage that the separation of ice is smooth.

Hereinafter, a preferred embodiment of the refrigerator according to the present invention having the configuration as described above will be described in detail.

Although not shown, a freezer compartment and a refrigerating compartment are generally formed inside the refrigerator body, and the freezer compartment and the refrigerating compartment are selectively opened and closed by a freezer compartment door and a refrigerating compartment door.

In addition, the freezer door is generally configured to open and close the left or right hinges to the left and right in the axis, or to open and close the bottom to the axis in the vertical, in the present invention will be described as an example of a refrigerator in which the door is opened and closed left and right.

3 and 4 are respectively a perspective view of the front and rear of the freezer door in which the refrigerator ice making means according to the present invention is installed.

First, FIG. 3 is a partial front view of the front side of the freezer compartment door 100 that selectively opens and closes the freezer compartment.

As shown in the figure, the home panel 110 is provided on the front surface of the freezing chamber door 100. The home bar panel 110 is formed of a square flat plate to form a front exterior of the freezing chamber door 100. The home panel 110 is a home panel of a freezer compartment, which is distinguished from a home bar and a home panel of a refrigerating chamber, which are generally installed.

A groove bar door 120 is formed in the groove bar panel 110. The home bar door 120 is formed at the lower half of the home bar panel 110 and is a dedicated home bar door 120 for withdrawing the outside (front) of the ice bank 230 to be described below. That is, a general home bar door is installed in the refrigerator compartment door to easily withdraw beverages stored in the refrigerator compartment to the outside without opening the refrigerator compartment door, whereas the home bar door 120 of the present invention is formed in the ice making room of the freezer compartment. Home bar door dedicated to the ice bank for withdrawal.

The upper half of the home bar panel 110 is formed with a display 112 and a plurality of operation buttons 114, respectively. The display unit 112 is a part in which an operating state of the ice making means 200 or an operating state of the freezing compartment, which will be described below, is displayed to the outside. And, the operation button 114 is to allow the user to operate or set the ice making means 200 to be described below from the outside.

4 shows a rear state of the freezer compartment door 100.

As shown in the figure, an ice making means 200 is provided on the rear surface of the freezing chamber door 100 to generate and store ice.

The ice making means 200 is provided with a bucket 210 for storing water, an ice making chamber 220 provided below the bucket 210 to generate ice, and a lower side of the ice making chamber 220. It consists of an ice bank 230 for storing ice.

In more detail, a rectangular box-shaped ice making case 202 forms a rough appearance of the ice making means 200, and an ice making chamber 220 in which ice is generated is formed in the center of the ice making case 202. .

The ice making chamber 220 is provided with a plurality of ice trays 224 to be described below, and a bucket 210 for supplying water to the ice tray 224 is installed above the ice making chamber 220. . In addition, an ice bank 230 in which ice generated in the ice making chamber 220 is temporarily stored is provided below the ice making chamber 220.

5 is a side cross-sectional view of the ice making means 200 is installed on the rear surface of the freezing chamber door 100.

As shown in the figure, the water tank 210 is provided with an opening and closing lever 212 for controlling the water stored in the water tank 210 to selectively drop to the lower side. That is, the opening and closing lever 212 selectively opens and closes the water supply port 214 which is formed to penetrate up and down on the bottom surface of the water tank 210 so that the water inside the water tank 210 is selectively dropped downwards to form the ice making chamber. To be introduced to (220).

The ice making chamber 220 is further provided with an interference lever 222. The interference lever 222 is installed so that the end interferes with one end of the opening and closing lever 212. Therefore, when the bucket 210 is mounted, the end of the interference lever 222 pushes the opening and closing lever 212 upward, and the water supply port 214 is opened.

The ice making chamber 220 is provided with an ice tray 224 which is a case in which ice is produced. In more detail, two ice trays 224 are provided, an upper tray 224 ′ installed in the upper half of the ice making chamber 220, and a heart ray installed in the lower half of the ice making chamber 220. 224 ") and the like.

The ice tray 224 is partitioned into a plurality of spaces to freeze water accumulated in each space so that ice of a predetermined size is generated. Generally, the ice tray 224 is divided into a plurality of square spaces to form a rectangular ice block.

Meanwhile, a water plate 226 and a water supply pipe 226 'for guiding water to the heart ray 224 " are further provided in the ice making chamber 220. The water plate 226 has a dish shape. It is formed like a bowl to collect the water of the bucket 210 supplied from the water supply port 214, the water collected by the water plate 226 is the heart ray along the water supply pipe 226 ' 224 ". Therefore, the water supply pipe 226 ′ is long and vertically formed in the ice making chamber 220.

Looking in more detail, although not shown in detail, the inside of the bucket 210 is divided into two spaces from side to side, and the water supplied to the upper tray 224 'is stored in one space (for example, the left space). In another space (for example, the right space), water supplied to the heart ray 224 " is stored. Each of the left and right spaces includes a respective water supply port 214 and an opening / closing lever 212. FIG. .

Accordingly, the water in the left space of the bucket 210 immediately falls to the upper tray 224 ', and the water in the right space passes through the water dish 226 and the water supply pipe 226'. 224 ". The left and right spaces of the water tank 210 are formed to have the same size as the inner spaces of the upper tray 224 'and the heart ray 224". Therefore, when the water in the left and right spaces of the water tank 210 are all supplied to the ice tray 224, all the inner space of the ice tray 224 is filled with water.

On the other hand, by providing a rotational force to the outside of the ice making chamber 220, by moving the ice tray 224 to separate the ice generated therein moving ice driving mechanism for moving to the ice bank 230 It is provided. The moving motion driving mechanism may be formed in various configurations to provide a rotational force, but the following description will be given as an example in which an moving lever 240 configured to be gripped and rotated by a user is provided.

The ice lever 240 is to ice the ice tray 224 so that the ice generated in the ice tray 224 falls into the ice bank 230. It is installed to surround the ice chamber 220.

In addition, the tray gears 310 and 312 to be described below are fixed to each other on the side of the ice tray 224, and the tray gears 310 and 312 are fastened to the moving lever 240. Therefore, when the user lowers the moving lever 240 downward, the ice tray 224 rotates to drop the ice inside the ice bank 230.

The groove bar door 120 is installed to open forward (right in FIG. 5) with the lower end as an axis. Thus, a door hinge 122 is provided at the lower end of the home bar door 120 to become a rotation center of the home bar door 120.

The fastening hook 124 is installed at the upper rear side (left side in FIG. 5) of the groove bar door 120. The fastening hook 124 is a mechanism for maintaining the home bar door 120 is closed to the freezing chamber door 100. Therefore, the freezing chamber door 100 is provided with a hook fixing body 126 for selectively hanging and fastening the fastening hook 124.

The hook fixing body 126 is a device for selectively fixing the fastening hook 124, when the user presses the upper end to the rear side (left in FIG. 5) in the state in which the home bar door 120 is opened, the fastening When the user presses the upper end of the home bar door 120 to the rear side (left side in FIG. 5) while the home bar door 120 is closed, the fastening hook 124 is detached from the hook 124. The home bar door 120 to be opened. Since the opening and closing device of the home bar door 120 is the same as the home bar door opening and closing device of a refrigerator generally used, a detailed description thereof will be omitted.

6A and 6B illustrate the connection configuration of the home bar door 120 and the ice bank 230 in more detail. That is, Figure 6a is an exploded perspective view showing a detailed configuration of the home bar door 120 and the ice bank 230, Figure 6b is a side cross-sectional view of the home bar door 120 and the ice bank 230. It is.

As shown in these figures, the ice bank 230 is formed in a rectangular box shape with an upper opening, and the left and right (before and after in Figure 6a) of the bottom is recessed to the inside and the movement guide 280 to be described below It is formed so as not to interfere.

A plurality of fixing protrusions 232 protruding downward are formed on the bottom surface of the ice bank 230. The fixing protrusion 232 is accommodated in the fixing groove 258 of the bank support plate 250 to be described below to force the ice bank 230 to flow together back and forth while being placed on the bank support plate 250 to be described below. do.

Meanwhile, bank handles 234 and 236 are formed at lower ends of the ice bank 230 before and after (left and right in FIGS. 6A and 6B). That is, the front handle 234 is provided at the front end of the ice bank 230 (the right end in FIGS. 6A and 6B), and the rear handle of the rear end of the ice bank 230 (the left end in FIGS. 6A and 6B). 236 is provided. The front handle 234 and the rear handle 236 is a portion which the user grips to pull the ice bank 230 forward and backward (left and right in FIGS. 6A and 6B).

The lower side of the ice bank 230 is provided with a bank support plate 250 that can slide back and forth. That is, the bank support plate 250 supports the ice bank 230 and is installed on the bottom surface of the ice making case 202.

The bank support plate 250 is preferably made of a flat plate having a predetermined thickness, and the front end (right end in FIG. 6A) has a central portion recessed to the rear (left side in FIG. 6A) so that one end of the link 260 will be described below. The link receiving portion 252 is formed. In addition, support plate grooves 254 into which the support plate protrusions 262 to be described below are inserted are formed at the left and right sides of the link receiving portion 252 (before and after FIGS. 6A and 6B).

At the rear end of the bank support plate 250 (the left end in FIG. 6A), a moving roller 256 is provided. The moving roller 256 is to allow the bank support plate 250 to move smoothly back and forth within the ice making case 202, and the rear end left and right side ends of the bank support plate 250 (left end in FIGS. 6A and 6B). And the rear end) is rotatably installed.

A plurality of fixing grooves 258 recessed downward are formed on the upper surface of the bank support plate 250. The fixing groove 258 is a portion in which the fixing protrusion 232 of the bottom surface of the ice bank 230 described above is received and coupled to each other. Therefore, the fixing groove 258 and the fixing protrusion 232 is preferably molded in a shape corresponding to the number corresponding to the position corresponding to each other.

A connection link 260 is further provided on the rear side of the home bar door 120 (the left side in FIGS. 6A and 6B). The connection link 260 is to allow the home bar door 120 and the bank support plate 250 to interlock with each other, and is formed of a flat plate having a predetermined thickness as shown.

Support plate protrusions 262 rotatably inserted into the support plate grooves 254 are formed on both sides of the lower ends of the connection links 260 to protrude outward. Therefore, the lower end of the connection link 260 and the front end of the bank support plate 250 (the right end in FIGS. 6A and 6B) are hinged to each other.

Door protrusions 264 protrude outward from both sides of the upper end of the connection link 260. The door protrusions 264 are rotatably inserted into the door grooves 274 formed in the groove bar door 120 to be described below.

Hinge protrusions 122 ′, which are the centers of rotation of the groove bar doors 120, protrude outward from both sides of the lower ends of the groove bar doors 120. In addition, a guide part 270 protruding to a rear side (left side in FIGS. 6A and 6B) is formed at a rear surface (left side in FIGS. 6A and 6B) of the groove bar door 120. The inside is recessed to the inside (right side in FIGS. 6A and 6B) to form a receiving portion 272 which is a predetermined space. The receiving portion 272 is a portion in which the upper half of the connection link 260 is accommodated.

Door grooves 274 are formed at left and right upper ends of the accommodation portion 272, respectively. The door grooves 274 are portions in which the door protrusions 264 of the connection links 260 described above are rotatably inserted, respectively. Therefore, when the door protrusion 264 of the connection link 260 is inserted into the door groove 274 of the home bar door 120, the upper end of the connection link 260 is connected to the upper half of the home bar door 120. The bank support plate 250 moves forward and backward (left and right in FIGS. 6A and 6B) in conjunction with the opening of the home bar door 120.

Meanwhile, a movement guide 280 as shown in FIGS. 7 and 8 is formed at the bottom side of the ice making case 202 before and after. That is, the moving guide 280 protruding inwardly is formed long on the upper side spaced apart from the bottom surface 202 ′ of the ice making case 202. Therefore, the moving roller 256 is positioned between the bottom surface 202 ′ of the ice making case 202 and the moving guide 280 to guide the front and back.

9 to 11 illustrate the internal structure of the ice making chamber 220 in more detail. That is, a perspective view of the ice making chamber 220 is shown in FIG. 9, a part of the inside of the ice making chamber 220 is partially shown in FIG. 10, and a side view of the ice tray 224 is shown in FIG. 11. have.

As shown in these drawings, the ice making chamber 220 is surrounded by a tray case 300 having a rectangular box shape with upper and lower openings, and the rear surface 302 of the tray case 300 is made of a transparent material. Consists of the formed to see through the inside. Therefore, the user can perform the ice-making work while observing the inside of the ice-making chamber 220 from the outside.

In addition, cold backpipes 304 serving as flow paths of cold air are formed on the rear surface 302 of the tray case 300, respectively. More preferably, the cooling pipe port 304 is formed at the rear side (the front side in FIG. 9) of the upper tray 224 ′ and the heart ray 224 ″.

The right side of the tray case 300 is provided with a gear case 306 to form a predetermined space. The front and rear surfaces of the gear case 306 and the upper and lower ends thereof have a lever guide groove 308 communicating with each other. The lever guide groove 308 is a portion in which the moving lever 240 is inserted and flows.

A plurality of tray gears 310 and 312 are installed in the gear case 306. The tray gears 310 and 312 are gears having gears formed on an outer circumferential surface thereof.

The tray gears 310 and 312 are installed to have the same rotation axis as the ice tray 224 and transmit rotational power to the ice tray 224. That is, the ice tray 224 is connected to the rotary shafts of the tray gears 310 and 312 to rotate integrally.

In more detail, the tray gears 310 and 312 may be coupled to the right side of the upper tray 224 ′ and the lower gear 312 coupled to the right side of the heart ray 224 ″. In addition, the upper tray 224 ′ is connected to the rotary shaft of the fish 310, and the heart ray 224 ″ is integrally connected to the rotary shaft of the lower gear 312. Accordingly, the fish 310 and the upper tray 224 ′, and the fish 312 and the heart ray 224 ″ are integrally rotated.

A connecting gear 314 is further provided between the fish 310 and the fish 312. That is, the connecting gear 314 is installed between the fish 310 and the lower gear 312, and serves to transfer the rotational force of the lower gear 312 to the upper gear 310.

The connecting gear 314 is a gear in which gears are formed on the outer circumferential surface similarly to the above-described gear 310 and the lower gear 312. That is, gears corresponding to each other are formed on the outer circumferential surfaces of the gear 310, the lower gear 312, and the connecting gear 314, and are coupled to each other by gear coupling. Therefore, when the gear 312 rotates, the gear 310 also rotates in the same direction.

As described above, the moving lever 240 is a moving motion driving mechanism, and an end portion thereof is connected to at least one tray rotating shaft of the plurality of ice trays 224.

The moving lever 240 has a '-' shape as shown, and is installed to surround the tray case 300. And, the end of the moving lever 240 is installed on the rotation axis of the heart ray 224 ".

Looking in more detail, the moving lever 240, the right end is fixedly connected to the right axis of rotation of the gear 312, the left end is integrally installed on the left axis of rotation of the gear 312. . In this case, an end portion of the moving lever 240 is integrally installed on the same rotation axis as the lower gear 312 and the heart ray 224 ". Accordingly, according to the rotation of the moving lever 240 The gear 312 and the heart ray 224 ″ rotate simultaneously.

The ice tray 224 includes a tray body 320 in which water is frozen and a tray cover 322 coupled to an upper side of the tray body 320. As shown, a plurality of icing spaces are formed in the tray body 320, and the tray cover 322 serves to prevent overflow of water stored in the tray body 320.

The center portion of the tray cover 322 is configured to penetrate up and down to allow cold and water to fall, and the rear end of the tray cover 322 (the left end in FIG. 11) is the rear end of the tray body 320. 11 is hinged to the left end). That is, a cover hinge 324 is provided at the rear end of the tray cover 322 (left end in FIG. 11) to allow the tray cover 322 to be rotatably coupled to the tray body 320.

On the other hand, the left and right sides (front and back in Figure 11) of the ice tray 224 is formed with a tray rotating shaft 326 protruding to the left and right. The tray rotating shaft 326 is to be the rotation center axis of the ice tray 224, the tray rotating shaft 326 formed on the right end (rear side in Figure 11) is fixedly connected to the gear 312, the left end The tray rotating shaft 326 (in front of FIG. 11) is rotatably installed on the left side of the tray case 300.

At the rear end of the ice tray 224 (rear end in FIG. 11), the rotation guide protrusion 328 is formed to protrude to the left side (front in FIG. 11). The rotation guide protrusion 328 flows along the rotation guide groove 335 to be described below to guide the rotation of the ice tray 224 and simultaneously control the degree of rotation.

Meanwhile, as shown in FIG. 10, the support protrusion 330 protrudes to the inner side (right side) of the left inner wall of the tray case 300. The support protrusion 330 is made of a flat plate having a predetermined thickness, and serves to support the rear lower end of the ice tray 224. That is, when the ice tray 224 is horizontal, the lower end is placed on the upper surface of the support protrusion 330.

A spring fixing groove 332 is formed on the upper surface of the support protrusion 330. The spring fixing groove 332 is a portion to which the rear end of the return member 340 to be described below is inserted and fixed.

An upper portion of the support protrusion 330 is formed with an arc-shaped rotation guide groove 335. The rotation guide groove 335 is a portion in which the rotation guide protrusion 328 of the ice tray 224 is inserted and flows. Therefore, when the ice tray 224 is horizontal, the rotation guide protrusion 328 is located at the lower portion 'A', and when the ice tray 224 rotates for the ice, the upper ' It is located in the B 'part.

In front of the support protrusion 330 is further formed a cover stop protrusion 337 protruding inward. The cover stop protrusion 337 is a portion that selectively interferes with the front end portion (the right end portion in FIG. 11) of the tray cover 322 of the ice tray 224. That is, when the ice tray 224 rotates for the ice, the tip of the tray cover 322 is hooked to the cover stop protrusion 337 so that the tray cover 322 is no longer along the tray body 320. It will not rotate. Therefore, the ice inside the tray body 320 can be easily dropped downward.

A return member 340 is further provided at the left end of the ice tray 224. The return member 340 is to force the ice tray 224 is rotated by the moving lever 240, and then returned to the original shape, it is preferably made of a torsion spring as shown.

The return member 340 is installed so that the center portion of the tray rotating shaft 326 of the ice tray 224, the rear end is inserted into the spring fixing groove 332 of the support protrusion 330 is fixed. Then, the tip of the return member 340 is bent upward to form a hook 342. The hook 342 is a part that is hooked to the left end of the ice tray 224.

Therefore, the ice tray 224 is always trying to rotate in the counterclockwise direction by the rotational force applied from the return member 340, the support protrusion 330 is to stop this ice tray 224.

Hereinafter, the operation of the refrigerator according to the present invention having the configuration as described above will be described.

First, water must be supplied from the outside to the ice making means 200. In this case, the freezing chamber door 100 is opened as shown in FIG. 4, and then the upper end of the ice making case 202 is opened. To the outside.

Then, water is introduced into the water tank 210 divided into two parts, and the water tank 210 in which the water is built is returned to the inside of the ice making means 200 again.

At this time, when the bucket 210 is in the original position, the opening and closing lever 212 is moved upward by the interference lever 222. As such, when the open / close lever 212 moves upward, the water supply port 214 is opened so that the water in the bucket 210 falls downward.

The water dropped from the bucket 210 is filled in the upper tray 224 ′ and the heart ray 224 ″. As described above, when water is supplied to the bucket 210, the bucket 210 is filled. Of water is automatically configured to fall into the ice tray 224.

As described above, after the water is supplied to the ice making means 200 from the outside, the user closes the freezer door 100. In this case, water accumulated in the ice tray 224 is frozen by the cold air in the freezer compartment, thereby producing ice.

When ice occurs in the ice tray 224 to generate ice, the user opens the freezer door 100 again, and pulls the ice lever 240 downward. In this case, the ice tray 224 is twisted and rotated, at which time the ice cubes fall into the ice bank 230.

The process of separating the ice inside by rotating the ice tray 224 will be described in more detail with reference to FIG. 13.

As described above, when the center portion of the moving lever 240 is pulled downward while holding by the hand, the gear 312 fixed to the moving lever 240 rotates in a counterclockwise direction. When the lower gear 312 rotates counterclockwise, the connecting gear 314 rotates clockwise, and thus the gear 310 rotates counterclockwise.

As such, when the gear 312 and the fish 310 rotate counterclockwise, the heart ray 224 ″ and the upper tray 224 ′ connected thereto also rotate counterclockwise. While the tray cover 322 is rotated while being closed by the tray body 320, the front end portion of the tray cover 322 collides with the cover stop protrusion 337, which causes the tray cover 322 to rotate. Therefore, the tray cover 322 is gradually opened.

Meanwhile, as the ice tray 224 rotates, the rotation guide protrusion 328 flows along the rotation guide groove 335. Then, when the rotation guide protrusion 328 reaches the upper end ('B' in Figure 10) of the rotation guide groove 335, the left end of the ice tray 224 is to stop the rotation. Therefore, from this time, the ice inside the ice tray 224 is torn apart to separate the ice, and by this process the ice inside the ice tray 224 is separated and falls into the ice bank 230.

Next, when all of the ice in the ice tray 224 is dropped into the ice bank 230, the user releases the moving lever 240. In this case, by the restoring force of the return member 340, the heart ray 224 "and the upper tray 224 'are rotated in the clockwise direction to return to the original (horizontal), wherein the moving lever 240 is It moves up along the lever guide groove 308 and is returned to its original position.

Of course, the operation of pulling the moving lever 240 downward as described above may be made several times. That is, since the rear surface 302 of the tray case 300 is made of a transparent material, the user continues to perform the ice work while directly checking whether the ice inside the ice tray 224 has been separated and dropped. can do.

After the ice is dropped into the ice bank 230 by the above process, the user closes the freezer door 100 and opens the home bar door 120 whenever necessary to open the ice in the ice bank 230. It will be able to withdraw to the outside.

Referring to Figures 5 to 12 look at the process of withdrawing the ice stored in the ice bank 230 to the outside in more detail as follows.

First, the user pushes the top of the home bar door 120 to the rear side. In this case, the fastening hook 124 fixed by the hook fixing body 126 is released from the hook fixing body 126, so that the groove bar door 120 is opened and is in a state as shown in FIG.

In more detail, as the home bar door 120 rotates forwardly (clockwise in FIG. 5) about the lower door hinge 122, the connection link 260 also watches in an upright state as shown in FIG. 6B. Direction of rotation.

As the connection link 260 rotates in the clockwise direction (FIGS. 5 to 6b), the bank support plate 250 connected to the connection link 260 is also forward (right side in FIGS. 5 to 6b). Will be moved to. That is, since the vertical length of the connection link 260 is relatively shorter than the vertical length of the groove bar door 120, when the groove bar door 120 is completely opened as shown in FIG. 12, the bank support plate 250 Is to be moved a portion forward (right in Figures 5-6B).

As such, when the bank support plate 250 moves forward (right side in FIGS. 5 to 6B), the ice bank 230 placed on an upper surface of the bank support plate 250 also front (right side in FIGS. 5 to 6B). Will be moved to. Thus, a portion of the tip of the ice bank 230 is exposed to the front outside of the freezer door 100 (see FIG. 12).

At this time, since the fixing protrusion 232 formed on the bottom surface of the ice bank 230 is accommodated in the fixing groove 258 formed in the bank support plate 250, the ice bank (230) is drawn out in front of the bank support plate 250. 230 is simultaneously drawn out forward without sliding, and at this time, the moving roller 256 formed at the rear end of the bank support plate 250 may allow the bank support plate 250 and the ice bank 230 to move forward more easily. Done.

By the above process, after the portion of the ice bank 230 is exposed to the outside as shown in FIG. 12, the user can immediately take the ice inside the ice bank 230, to take more ice In this case, the ice bank 230 is further drawn out.

In more detail, when the user applies a force forward while holding the front handle 234 of the ice bank 230 in the state as shown in Figure 12, the ice bank 230 is the upper surface of the bank support plate 250 It is pulled forward while sliding.

At this time, the user is more preferably pulled forward while lifting the front end portion of the ice bank 230 by a predetermined portion while holding the front handle 234. That is, since the fixing protrusion 232 of the ice bank 230 is inserted into the fixing groove 258 of the bank support plate 250 as shown in FIG. 6B, the tip portion of the ice bank 230 is slightly lifted. When the force is applied to the front, the fixing protrusion 232 will be out of the fixing groove 258, so that the withdrawal of the ice bank 230 will be possible with less force.

After extracting the ice inside the ice bank 230 as described above, the ice bank 230 is returned to its original position. In this case, the ice bank 230 is reversed.

That is, in this case, the ice bank 230 is pushed backward so that the fixing protrusion 232 at the bottom of the ice bank 230 is accommodated in the fixing groove 258 of the bank support plate 250. In this case, a state as shown in FIG. 12 is obtained.

At this time, the tip of the home bar door 120 is lifted to close the home bar door 120. That is, the fastening hook 124 is inserted into the hook fixing body 126 by pushing the upper end of the groove bar door 120 backward. In this case, since the hook fixing body 126 fixes the fastening hook 124, the home bar door 120 is maintained in a closed state as shown in FIG.

Of course, at this time, the connection link 260 is also standing upright with the uprights of the home bar door 120, and at the same time the bank support plate 250 is pushed back (left in Figs. 5 to 6b) and It is in the same state.

In addition, the ice bank 230 may be withdrawn to the rear (left in FIG. 5). That is, when the rear door 236 of the ice bank 230 is pulled in the state in which the freezer door 100 is opened, the ice bank 230 slides the upper surface of the bank support plate 250. Pulled out backward.

The scope of the present invention is not limited to the above-described embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the scope of the present invention.

For example, although the torsion spring is used as the return member 340 in the above embodiment, various return members may be used in addition to the torsion spring. That is, many other means for providing rotational force such that the ice tray 224 is in place may be applied.

In addition, in the above embodiment, the end of the moving lever 240 is installed to be coaxially connected with the heart ray 224 "and the lower gear 312, but the end of the moving lever 240 is Of course, the upper tray 224 ′ and the control unit 310 may be installed on the same axis.

In the ice making means of the refrigerator according to the present invention as described in detail above, a 'c' shaped ice lever is provided to rotate a plurality of ice trays simultaneously. Therefore, there is an advantage that the work efficiency is improved by easily separating the ice provided in the plurality of ice trays.

In addition, in the present invention, since the rear surface of the ice making case (tray case) is made of a transparent material, the user can directly see the state of the ice making operation. Therefore, since the operation of the ice tray and the separation state of the ice, as well as the normal operation state of the product, such as the return of the ice tray can be immediately confirmed, there is an advantage that the damage of the product due to the failure is prevented.

Claims (10)

delete An ice making chamber provided on the rear surface of the freezing chamber door to generate ice; A water tank provided at an upper side of the ice making chamber to supply water to the ice making chamber; It is provided below the ice-making chamber, and has a configuration including an ice bank for storing the ice generated in the ice-making chamber; The ice making room, And an ice tray for freezing water, a tray gear provided at one side of the ice tray, an ice lever for transmitting rotational power to the tray gear, and a return member for applying rotational force to one side such that the ice tray is in the original position. The ice making means of the refrigerator, characterized in that for wrapping the outside of the ice making room. The method of claim 2, wherein the moving lever, It is formed in a 'c' shape, the end of the ice making means of the refrigerator characterized in that fixed to the tray gear. 4. The ice making means of claim 3, wherein the ice tray and the tray gear are provided in plural, and each ice tray and the tray gear are rotated by the same rotation shaft. 5. The ice making means of claim 4, wherein a connection gear for connecting each tray gear is further provided between the plurality of tray gears, and the moving lever is connected to any one of the plurality of tray gears. 6. The ice making means according to claim 5, wherein gears corresponding to each other are formed on outer circumferential surfaces of the plurality of tray gears and the connection gears, and gears are coupled to each other. A tray case provided on the rear surface of the freezing chamber door to form a predetermined space; A bucket provided at an upper portion of the tray case and storing water for ice making; A plurality of ice trays rotatably mounted inside the tray case below the bucket and spaced vertically to make ice; An ice bank provided below the ice tray and configured to store the ice made from the ice tray and iced; A pair of tray gears provided on each of the rotation shafts of the plurality of ice trays; It is provided in the tray case, comprising a moving lever for rotating the pair of tray gears at the same time by a user's rotation operation, The ice making means of the refrigerator, characterized in that the at least part is accommodated inside the tray case. The method of claim 7, wherein At least a portion of the ice lever is accommodated in the tray case, the ice making means of the refrigerator, characterized in that the lever guide groove for guiding the rotation of the ice lever is formed. The method of claim 7, wherein The ice making means of the refrigerator, characterized in that the rotating shaft of the ice tray is provided with a return member for providing elasticity so that the ice tray can be rotated back to its original position after rotation. The method of claim 7, wherein The moving lever is, It is connected to the left and right rotating shafts provided on any one of the plurality of ice trays, and the central portion connecting the left and right sides extending from the rotating shafts of both sides is formed to be exposed to the outside of the tray case is configured to be operated by the user Ice making means of the refrigerator, characterized in that.

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