A CRASHED ICE MAKING MACHINE AND REFRIGERATOR WHEREIN THE SAME IS USED

Abstract

The present invention relates to a crashed ice making machine (1) comprising an ice container (4) having at least one partition (5) wherein water can be filled and that enables ice to be formed by the water filled therein being frozen in the cold environment; an ice dispensing mechanism (A) that enables the ice to be pushed out of the ice container (4), an ice cutting mechanism (B) that is placed at the inlet portion of the ice container (4) and that cuts the ice pushed out of the ice container (4) by rotating thus providing crashed ice, and a driving mechanism (D) that drives the ice dispensing mechanism (A) and the ice cutting mechanism (B); and also relates to a refrigerator wherein the said crashed ice making machine (1) is used.

Description

The present invention relates to a crashed ice making machine and a refrigerator wherein the same is used.

Producers of white goods design a large number of different types of crashed ice making machines and refrigerators wherein the same is used in order to meet the crashed ice need of consumers. The crashed ice making machines occupy large space due to their complex structures and reduce the usable volume of the refrigerators. Since the consumers prefer refrigerators with large inner volumes, producers of white goods prefer using small crashed ice making machines in refrigerators. Small crashed ice making machines produce limited crashed ice and cannot fully meet the need of consumers.

In order to solve this problem, producers of white goods design crashed ice making machines that are plain in mechanical terms and that occupy less space.

In the state of the art International Patent Application No. WO2010/131867A2, an ice maker is described, having a driving unit and wherein a single electric motor that enables the ice separating unit and the ice elevating unit to be driven.

The aim of the present invention is the realization of a crashed ice making machine that is plain in mechanical terms and can be operated efficiently, that occupies a small space, that does not reduce the inner volume of the refrigerator and efficiently meets the crashed ice need of the user.

The crashed ice making machine realized in order to attain the aim of the present invention, explicated in the attached claims is suitable to be used in a refrigerator and comprises an ice dispensing mechanism having at least one pushing mechanism that is placed into the partition so as to linearly rise and descend between the base portion and the inlet portion of the ice container, that moves upwards when driven forwards by the driving mechanism and thus pushes and enables the ice to be dispensed from the ice container and that moves downwards when driven backwards by the driving mechanism and thus discharges the partition in order to fill in water. Thus, the entire inner volume of the partition is enabled to be used for making ice. Moreover, the entire ice formed in the ice container is enabled to be dispensed from the ice container. Thus, when fresh water is filled into the partition in the next crashed ice making cycle, water is not added onto the remainder ice remaining inside the partition contrary to the case with the present crashed ice making machines. Consequently, the crashed ice need of the user is provided with the frozen fresh water in each cycle.

In an embodiment of the present invention, the ice container comprises more than one partition wherein water can be filled. Ice can be formed separately in each partition with the water filled into the ice container partitions being frozen in the cold environment. Moreover, the ice dispensing mechanism comprises more than one pushing mechanism, each placed into one partition so as to linearly rise and descend between the base portion and the inlet portion of the partition. When driven forwards by the driving mechanism, each pushing mechanism rises and thus pushes and dispenses the ice from the partition. Furthermore, when driven backwards by the driving mechanism, each pushing mechanism descends and discharges the partition in order to fill in water. Thus, the inner volumes of the ice container partitions are enabled to be used more effectively. Consequently, a large amount of crashed ice can be formed and the crashed ice need of the user can be efficiently met.

In an embodiment of the present invention, the ice cutting mechanism comprises an ice cutting blade that is placed at the inlet portion of the ice container and provides crashed ice by rotating and cutting the ice pushed out of the ice container. Thus, the ice is enabled to be cut while being pushed out of the ice container.

In an embodiment of the present invention, the lower surface of the ice cutting blade is realized so as to be seated onto the inlet of the ice container in a flat manner. Thus, the ice cutting blade is enabled to be operated in a balanced manner and safely driven. The upper surface of the ice cutting blade is inclined. Thus, the ice can be cut as thin layers.

In an embodiment of the present invention, the driving mechanism comprises a motor and a transmission mechanism that can be rotated by the motor and that has at least one worm and at least one gear placed outside the ice container partitions. Thus, the entire inner volume of the partition is enabled to be used for making ice. The transmission mechanism drives both the ice cutting mechanism and each pushing mechanism. Each pushing mechanism is driven by the transmission mechanism so as to rise and descend in the ice container. The ice cutting mechanism is driven by the transmission mechanism so as to cut the ice pushed out of the ice container by rotating. Thus, a crashed ice making machine that operates efficiently and that is plain in mechanical terms is obtained. In an embodiment of the present invention, the transmission mechanism comprises a worm. The worm is placed outside the ice container partitions so that the rotational axis thereof is parallel to the axis of the ice container partitions in the base-inlet direction. Thus, the crashed ice making machine is enabled to have a small width and to occupy a small space.

In an embodiment of the present invention, the ice cutting mechanism that cuts the ice pushed out of the ice container by rotating is connected to the end of the worm so as to pass over the inlet portion of the ice container partitions. Thus, an ice cutting mechanism that operates efficiently and that is plain in mechanical terms is obtained. Moreover, the cutting mechanism can be more easily serviced and repaired.

In an embodiment of the present invention, the ice cutting mechanism is placed so that the rotational plane thereof is parallel to the plane formed by the inlet portions of the ice container partitions. Moreover, the ice container partitions are placed at equal intervals around the rotational axis of the ice cutting mechanism. Thus, the crashed ice making machine is enabled to occupy a small space.

In an embodiment of the present invention, each partition is realized as a receptacle that extends linearly in the base-inlet direction. The cross-section of each partition remains stationary along the axis thereof in the base-inlet direction. Thus, there is no unusable volume left between the partitions. Moreover, the crashed ice making machine is enabled to occupy a small space.

In another embodiment of the present invention, the cross-section of each ice container partition widens from the base portion towards the inlet portion along the axis thereof in the base-inlet direction. Thus, after being pushed and separated from the ice container partitions, the ice is enabled to be easily pushed out of the ice container partitions. Moreover, in the case that water is filled into the partition without taking the entire ice out of the ice container, the remainder ice is enabled to rise freely towards the inlet portion of the ice container, to freeze together with the newly forming ice at a position close to the inlet portion and to be cut firstly at the next cycle, thereby providing crashed ice. Thus, the remainder ice is prevented from getting stuck to the base of the ice container and remaining at the base of the ice container for a long time. Consequently, dirt accumulation in the ice container is prevented.

In another embodiment of the present invention, the cross-section of each ice container partition perpendicular to the axis thereof in the base-inlet direction is configured preferably in circular, triangular, square, rectangular or trapezoidal form. Thus, thin ice layers obtained by cutting have proper shapes. Thus, the ice container volume is enabled to be used more effectively in order to make ice.

In an embodiment of the present invention, the ice container comprises an inlet port that opens to at least one partition and that enables water to be filled into the partition. Moreover, the ice container comprises water passage openings that enable the water to pass from one partition to another partition. Thus, the ice container is enabled to be filled with water before the next crashed ice making cycle.

In an embodiment of the present invention, the pushing mechanism is realized by means of a pushing shaft that extends into the partition through an opening formed at the base portion of the ice container and skidded to the ice container opening over a sealing element so as to rise and descend. When the portion of the pushing shaft remaining outside the ice container is driven upwards by the driving mechanism, the portion thereof remaining inside the partition rises, pushes the ice towards the partition inlet and out of the partition. When the portion of the pushing shaft remaining outside the ice container is driven downwards by the driving mechanism, the portion thereof remaining inside the partition descends and discharges the partition in order to fill in water. It is not compulsory for the pushing mechanism to be composed of a pushing shaft. In another embodiment of the present invention, the pushing mechanism comprises more than one gear-shaft that is placed at the base portion of the partition and that can open/close telescopically, one being screwed onto the other so as to rotate freely around an axis perpendicular to the partition base. When driven forwards by the driving mechanism, the gear-shafts change from a closed position to a telescopically open position and push the ice out of the ice container. When driven backwards by the driving mechanism, the gear-shafts changes from the telescopically open position to the closed position and discharges the partition in order to fill in water. Thus, the entire inner volume of the partition is enabled to be used for making ice. Moreover, the entire ice formed in the ice container is enabled to be pushed out of the ice container. Moreover, the crashed ice making machine is enabled to occupy a small space.

In an embodiment of the present invention, the ice container comprises more than one partition wherein water can be filled. A pushing mechanism is provided in each partition. Each pushing mechanism is realized by means of a pushing shaft that extends into the partition through an opening formed at the base portion of the partition and skidded to the partition opening over a sealing element so as to rise and descend. Moreover, the ice dispensing mechanism comprises a geared or screwed shaft carrier driven by the driving mechanism and whereon the pushing shafts are fixed. In another embodiment of the present invention, the pushing mechanism in each partition comprises more than one gear-shaft that is placed at the base portion of the partition and that can open/close telescopically, one being screwed onto the other so as to rotate freely around an axis perpendicular to the partition base.

In an embodiment of the present invention, the crashed ice making machine comprises a stopping mechanism that limits the forwards-backwards movement of the shaft carrier. Thus, the crashed ice making machine is enabled to be operated in a safe manner.

In an embodiment of the present invention, the stopping mechanism comprises a stopper realized as a first flange that is situated on the shaft carrier and that limits the forwards movement of the shaft carrier. In an embodiment of the present invention, the stopping mechanism furthermore comprises a second stopper realized as a second flange that is situated on the lower side of the worm in the driving mechanism and that limits the backwards movement of the shaft carrier. Thus, the forwards-backwards movement of the shaft carrier is limited.

In an embodiment of the present invention, the refrigerator comprises a freezing compartment, a crashed ice making machine of the present invention placed into the freezing compartment, a control unit that controls the driving mechanism of the crashed ice making machine and the water filling mechanism filling the ice container with water, and a crashed ice collection receptacle that is stationary or detachable, that can be accessed from inside or outside the refrigerator and wherein crashed ice pieces produced by the crashed ice making machine are collected. Thus, the user is enabled to easily reach the crashed ice pieces.

By means of the present invention, a crashed ice making machine is realized, that is plain in mechanical terms and can be operated efficiently, that occupies a small space, that does not reduce the inner volume of the refrigerator and efficiently meets the crashed ice need of the user.

The model embodiments relating to the crashed ice making machine realized in order to attain the aim of the present invention are illustrated in the attached figures, where:

FIG. 1—is a perspective view of the crashed ice making machine with its components separated in an embodiment of the present invention.

FIG. 2—is a perspective view of the crashed ice making machine in an embodiment of the present invention.

FIG. 3—is another perspective view of the crashed ice making machine in an embodiment of the present invention.

The elements illustrated in the figures are numbered as follows:

1. Crashed ice making machine

2. Ice cutting blade

3. Blade fixing member

4. Ice container

5. Partition

6. Inlet port

7. Sealing element

8. Ice pushing shaft

9. Shaft carrier

10. First flange

11. Transmission mechanism

12. Second flange

13. Motor

In all embodiments of the present invention, the crashed ice making machine (1) comprises an ice container (4) having at least one partition (5) wherein water can be filled and that enables ice to be formed by the water filled therein being frozen in the cold environment; an ice dispensing mechanism (A) that enables the ice to be pushed out of the ice container (4) and that has a sealing element (7), at least one ice pushing shaft (8), a shaft carrier (9) and a first flange (10); an ice cutting mechanism (B) that is placed at the inlet portion of the ice container (4), that cuts the ice pushed out of the ice container (4) by rotating thus providing crashed ice and that has an ice cutting blade (2) and a blade fixing member (3); and a driving mechanism (D) that drives the ice dispensing mechanism (A) and the ice cutting mechanism (B) and that has a transmission mechanism (11), a second flange (12) and a motor (13) (FIG. 1, FIG. 2, FIG. 3).

In all embodiments of the present invention, the crashed ice making machine (1) comprises an ice dispensing mechanism (A) having at least one pushing mechanism (C) that is placed into the partition (5) so as to linearly rise and descend between the base portion and the inlet portion of the ice container (4), that moves upwards when driven forwards by the driving mechanism (D) and thus pushes and enables the ice to be dispensed from the ice container (4) and that moves downwards when driven backwards by the driving mechanism (D) and thus discharges the partition (5) in order to fill in water (FIG. 2, FIG. 3). Thus, the entire inner volume of the partition (5) is enabled to be used for making ice (FIG. 2, FIG. 3). Moreover, the entire ice formed in the ice container (4) is enabled to be dispensed from the ice container (4). Thus, when fresh water is filled into the partition (5) in the next crashed ice making cycle, water is not added onto the remainder ice remaining inside the partition (5) contrary to the case with the present crashed ice making machines. Consequently, the crashed ice need of the user is provided with the frozen fresh water in each cycle.

In an embodiment of the present invention, the ice container (4) comprises more than one partition (5) wherein water can be filled (FIG. 2, FIG. 3). Ice can be formed separately in each partition (5) with the water filled into the ice container (4) partitions (5) being frozen in the cold environment. Moreover, the ice dispensing mechanism (A) comprises more than one pushing mechanism (C), each placed into one partition (5) so as to linearly rise and descend between one base portion and one inlet portion of the partition (5) (FIG. 1, FIG. 2, FIG. 3). When driven forwards by the driving mechanism (D), each pushing mechanism (C) rises and thus pushes and dispenses the ice from the partition (5) (FIG. 1, FIG. 2, FIG. 3). Moreover, when driven backwards by the driving mechanism (D), each pushing mechanism (C) descends and discharges the partition (5) in order to fill in water (FIG. 1, FIG. 2, FIG. 3). Thus, the inner volumes of the ice container (4) partitions (5) are enabled to be used more effectively. Consequently, a large amount of crashed ice can be formed and the crashed ice need of the user can be efficiently met. The crashed ice making machine (1) shown in the figures has preferably seven partitions (5). However, the number of partitions (5) is not limited to seven. A single partition (5) is sufficient.

In an embodiment of the present invention, the ice cutting mechanism (B) comprises an ice cutting blade (2) that is placed at the inlet portion of the ice container (4) and provides crashed ice by rotating and cutting the ice pushed out of the ice container (4) (FIG. 1, FIG. 3). Thus, the ice is enabled to be cut while being pushed out of the ice container (4). The said cutting blade (2) is preferably produced from steel. The width of the ice cutting blade (2) is sized so as to fit into the region between two partitions (5). Thus, while the ice cutting blade (2) is rotating, the ice can be pushed out of the ice container (4).

In an embodiment of the present invention, a lower surface of the ice cutting blade (2) is realized so as to be seated onto the inlet of the ice container (4) in a flat manner (FIG. 3). Thus, the ice cutting blade (2) is enabled to be operated in a balanced manner and safely driven. An upper surface of the ice cutting blade (2) is inclined (8) (FIG. 3). Thus, the ice can be cut as thin layers.

In an embodiment of the present invention, the driving mechanism (D) comprises a motor (13) and a transmission mechanism (11) that can be rotated by the motor (13) and that has at least one worm and at least one gear placed outside the ice container (4) partitions (5) (FIG. 1). Thus, the entire inner volume of the partition (5) is enabled to be used for making ice. The transmission mechanism (11) drives both the ice cutting mechanism (B) and each pushing mechanism (C) (FIG. 1). Each pushing mechanism (C) is driven by the transmission mechanism (11) so as to rise and descend in the ice container (4) (FIG. 1, FIG. 2, FIG. 3). The ice cutting mechanism (B) is driven by the transmission mechanism (11) so as to cut the ice pushed out of the ice container (4) by rotating (FIG. 1, FIG. 2, FIG. 3). Thus, a crashed ice making machine (1) that operates efficiently and that is plain in mechanical terms is obtained.

In an embodiment of the present invention, the transmission mechanism (11) comprises a worm (FIG. 1). The worm is placed outside the partitions (5) so that the rotational axis (Z) thereof is parallel to the axis of the ice container (4) partitions (5) in the base-inlet direction (FIG. 1). Thus, the crashed ice making machine (1) is enabled to have a small width and to occupy a small space. The thickness of thin ice layers obtained by cutting is determined by the step of the worm.

In an embodiment of the present invention, the ice cutting mechanism (B) that cuts the ice pushed out of the ice container (4) by rotating is connected to the end of the worm so as to pass over the inlet portions of the partitions (5) (FIG. 1, FIG. 3). The ice cutting blade (2) in the ice cutting mechanism (B) is connected to the worm preferably by means of a blade fixing member (3). Thus, an ice cutting mechanism (B) that operates efficiently and that is plain in mechanical terms is obtained. Moreover, the ice cutting mechanism (B) can be more easily serviced and repaired.

In an embodiment of the present invention, the ice cutting mechanism (B) is placed so that the rotational plane thereof is parallel to the plane formed by the inlet portions of the partitions (5) (FIG. 3). Moreover, the partitions (5) are placed at equal intervals around the rotational axis of the ice cutting mechanism (B) (FIG. 3). Thus, the crashed ice making machine (1) is enabled to occupy a small space.

In an embodiment of the present invention, each partition (5) is realized as a receptacle that extends linearly in the base-inlet direction. The cross-section of each partition (5) remains stationary along the axis thereof in the base-inlet direction. Thus, there is no unusable volume left between the partitions (5). Consequently, the crashed ice making machine (1) is enabled to occupy a small space. In another embodiment of the present invention, the cross-section of each partition (5) widens from the base portion towards the inlet portion along the axis thereof in the base-inlet direction. Thus, after being pushed and separated from the partitions (5), the ice is enabled to be easily pushed out of the ice container (4) partitions (5). Moreover, in the case that water is filled into the partition (5) without taking the entire ice out of the ice container (4), the remainder ice is enabled to rise freely towards the inlet portion of the ice container (4), to freeze together with the newly forming ice at a position close to the inlet portion and to be cut firstly at the next cycle, thereby providing crashed ice. Thus, the remainder ice is prevented from getting stuck to the base of the ice container (4) and remaining at the base of the ice container (4) for a long time. Consequently, dirt accumulation in the ice container (4) is prevented.

In another embodiment of the present invention, the cross-section of each partition (5) perpendicular to the axis thereof in the base-inlet direction is configured preferably in circular, triangular, square, rectangular or trapezoidal form (FIG. 3). Thus, thin ice layers obtained by cutting have proper shapes. Thus, the ice container (4) volume is enabled to be used more effectively in order to make ice.

In an embodiment of the present invention, the ice container (4) comprises an inlet port (6) that opens to at least one partition (5) and that enables water to be filled into the partition (5) (FIG. 1, FIG. 2, FIG. 3). Moreover, the ice container (4) comprises water passage openings that enable the water to pass from one partition (5) to another partition (5) (FIG. 3). Thus, the ice container (4) is enabled to be filled with water before the next crashed ice making cycle.

In an embodiment of the present invention, the pushing mechanism (C) is realized by means of a pushing shaft (8) that extends into the partition (5) through an opening formed at the base portion of the ice container (4) and skidded to the ice container (4) opening over a sealing element (7) so as to rise and descend (FIG. 1). When the portion of the pushing shaft (8) remaining outside the ice container (4) is driven upwards by the driving mechanism (D), the portion thereof remaining inside the partition (5) rises, pushes the ice towards the partition (5) inlet and out of the partition (5). When the portion of the pushing shaft (8) remaining outside the ice container (4) is driven downwards by the driving mechanism (D), the portion thereof remaining inside the partition (5) descends and discharges the partition (5) in order to fill in water (FIG. 2 and FIG. 3). The length of the pushing shaft (8) is preferred to be such that when pushed entirely into the ice container (4), the pushing shaft (8) reaches the inlet of the ice container (4). Thus, the entire ice is enabled to be taken out of the ice container (4). It is not compulsory for the pushing mechanism (C) to be composed of a pushing shaft (8). In another embodiment of the present invention not shown in the figures, the pushing mechanism (C) comprises more than one gear-shaft that is placed at the base portion of the partition (5) and that can open/close telescopically, one being screwed onto the other so as to rotate freely around an axis perpendicular to the partition (5) base. When driven forwards by the driving mechanism (D), the gear-shafts change from a closed position to a telescopically open position and push the ice out of the ice container (4). When driven backwards by the driving mechanism (D), the gear-shafts change from the telescopically open position to the closed position and discharge the partition (5) in order to fill in water. Thus, the entire inner volume of the partition (5) is enabled to be used for making ice. Moreover, the entire ice formed in the ice container (4) is enabled to be pushed out of the ice container (4). Consequently, the crashed ice making machine (1) is enabled to occupy a small space.

In an embodiment of the present invention, the ice container (4) comprises more than one partition (5) wherein water can be filled (FIG. 3). A pushing mechanism (C) is provided in each partition (5). Each pushing mechanism (C) is realized by means of a pushing shaft (8) that extends into the partition (5) through an opening formed at the base portion of the partition (5) and skidded to the partition (5) opening over a sealing element (7) so as to rise and descend. Moreover, the dispensing mechanism (A) comprises a geared or screwed shaft carrier (9) driven by the driving mechanism (D) and whereon the pushing shafts (8) are fixed (FIG. 1). The pushing shafts (8) are fixed to the shaft carrier (9) preferably by screwing. The sealing element (7) is composed of a sealing element (7) (FIG. 1). In another embodiment of the present invention not shown in the figures, the pushing mechanism (C) in each partition (5) comprises more than one gear-shaft that is placed at the base portion of the partition (5) and that can open/close telescopically, one being screwed onto the other so as to rotate freely around an axis perpendicular to the partition (5) base.

In an embodiment of the present invention, the crashed ice making machine (1) comprises a stopping mechanism that limits the forwards-backwards movement of the shaft carrier (9). Thus, the crashed ice making machine (1) is enabled to be operated in a safe manner.

In an embodiment of the present invention, the stopping mechanism comprises a stopper realized as a first flange (10) that is situated on the shaft carrier (9) and that limits the forwards movement of the shaft carrier (9). In an embodiment of the present invention, the stopping mechanism furthermore comprises a second stopper realized as a second flange (12) that is situated on the lower side of the worm in the driving mechanism (D) and that limits the backwards movement of the shaft carrier (9). Thus, the forwards-backwards movement of the shaft carrier (9) is limited.

In an embodiment of the present invention not shown in the figures, the refrigerator comprises a freezing compartment, a crashed ice making machine (1) of the present invention placed into the freezing compartment, a control unit that controls the driving mechanism (D) of the crashed ice making machine (1) and the water filling mechanism filling the ice container (4) with water, and a crashed ice collection receptacle that is stationary or detachable, that can be accessed from inside or outside the refrigerator and wherein crashed ice pieces produced by the crashed ice making machine (1) are collected. Thus, the user is enabled to easily reach the crashed ice pieces.

In an embodiment of the present invention not shown in the figures, the refrigerator furthermore comprises a control panel connected to the control unit. Thus, the user is enabled to use the crashed ice making machine (1) via the control panel.

In an embodiment of the present invention not shown in the figures, a heating electric cable controlled by the control unit and provides the heating of the ice container (4) is wrapped around the ice container (4) in order that the ice is easily separated from the ice container (4) and taken out. However, it is not compulsory to use the electric cable. It is possible to take the ice out of the ice container (4) by using the pushing mechanism (C) without heating.

By means of the present invention, a crashed ice making machine (1) is realized, that does not reduce the inner volume of the ice container (4) nor the refrigerator, that is plain in mechanical terms and occupies a small space, that can be efficiently operated, and that enables the entire ice formed in the ice container (4) to be taken out of the ice container (4) and above all that efficiently meets the crashed ice need of the user.

The crashed ice making machine (1) shown in the figures has more than one partition (5). The crashed ice making machine (1) not shown in the figures and comprising a single partition (5) should be considered within the scope of the present invention.

Claims

1-A crashed ice making machine (1) comprising an ice container (4) having at least one partition (5) wherein water can be filled and that enables ice to be formed by the water filled therein being frozen in the cold environment, an ice dispensing mechanism (A) that enables the ice to be pushed out of the ice container (4) and that has a sealing element (7), at least one ice pushing shaft (8), a shaft carrier (9) and a first flange (10), an ice cutting mechanism (B) that is placed at the inlet portion of the ice container (4), that cuts the ice pushed out of the ice container (4) by rotating thus providing crashed ice and that has an ice cutting blade (2) and a blade fixing member (3), and a driving mechanism (D) that drives the ice dispensing mechanism (A) and the ice cutting mechanism (B) and that has a transmission mechanism (11), a second flange (12) and a motor (13), characterized by the ice dispensing mechanism (A) having at least one pushing mechanism (C) that is placed into the partition (5) so as to linearly rise and descend between the base portion and the inlet portion of the ice container (4), that moves upwards when driven forwards by the driving mechanism (D) and thus pushes and enables the ice to be dispensed from the ice container (4) and that moves downwards when driven backwards by the driving mechanism (D) and thus discharges the partition (5) in order to fill in water.

2-A crashed ice making machine (1) as in claim 1, characterized by an ice container (4) that has more than one partition (5) wherein water can be filled and that enables ice to be formed separately in each partition (5) by the water filled in the partitions (5) being frozen in the cold environment and by the ice dispensing mechanism (A) having more than one pushing mechanism (C), each placed into one partition (5) so as to linearly rise and descend between the base portion and the inlet portion of the partition (5), that moves upwards when driven forwards by the driving mechanism (D) and thus pushes and enables the ice to be dispensed from the partition (5) and that moves downwards when driven backwards by the driving mechanism (D) and thus discharges the partition (5) in order to fill in water.

3-A crashed ice making machine (1) as in claim 1, characterized by the ice cutting mechanism (B) comprising an ice cutting blade (2) that is placed at the inlet portion of the ice container (4) and provides crashed ice by rotating and cutting the ice pushed out of the ice container (4).

4-A crashed ice making machine (1) as in claim 3, characterized by the ice cutting blade (2), the lower surface of which is realized so as to be seated onto the inlet of the ice container (4) in a flat manner and the upper surface of which is realized to be inclined (θ).

5-A crashed ice making machine (1) as in claim 1, characterized by a motor (13), the driving mechanism (D) comprising a transmission mechanism (11) that can be rotated by the motor (13) and that has at least one worm and at least one gear placed outside the partitions (5), more than one pushing mechanism (C) each driven by the transmission mechanism (11) so as to rise and descend in the ice container (4) and the ice cutting mechanism (B) driven by the transmission mechanism (11) so as to cut the ice pushed out of the ice container (4) by rotating.

6-A crashed ice making mechanism (1) as in claim 5, characterized by the driving mechanism (D) comprising the transmission mechanism (11) having a worm placed outside the partitions (5) so that the rotational axis (Z) thereof is parallel to the axis of the partitions (5) in the base-inlet direction.

7-A crashed ice making machine (1) as in claim 6, characterized by the ice cutting mechanism (B) that is connected to the end of the worm so as to pass over the inlet portions of the ice container (4) partitions (5) and that cuts the ice pushed out of the ice container (4) by rotating.

8-A crashed ice making machine (1) as in claim 1, characterized by the partitions (5) that are placed at equal intervals around the rotational axis of the ice cutting mechanism (B) and the plane formed by the inlet portions thereof being parallel to the rotational plane of the ice cutting mechanism (B).

9-A crashed ice making machine (1) as in claim 1, characterized by the partitions (5), each shaped as a receptacle extending linearly in the base-inlet direction, the cross-section of each remaining stationary along the axis thereof in the base-inlet direction or the cross-section of each widening from the base portion towards the inlet portion along the axis thereof in the base-inlet direction.

10-A crashed ice making mechanism (1) as in claim 9, characterized by the partitions (5), the cross-section perpendicular to the axis thereof in the base-inlet direction of each being configured in circular, triangular, square, rectangular or trapezoidal form.

11-A crashed ice making machine (1) as in claim 1, characterized by the ice container (4) having an inlet port (6) that opens to at least one partition (5) and that enables water to be filled into the partition (5) and furthermore having water passage openings that enable the water to pass from one partition (5) to another partition (5).

12-A crashed ice making machine (1) as in claim 1, characterized by the pushing mechanism (C) realized by means of at least one pushing shaft (8) that extends into the partition (5) through an opening formed at the base portion of the ice container (4) and skidded to the ice container (4) opening over a sealing element (7) so as to rise and descend, wherein when the portion of the pushing shaft (8) remaining outside the ice container (4) is driven upwards by the driving mechanism (D), the portion thereof remaining inside the partition (5) rises, pushes the ice towards the partition (5) inlet and out of the partition (5) and wherein when the portion of the pushing shaft (8) remaining outside the ice container (4) is driven downwards by the driving mechanism (D), the portion thereof remaining inside the partition (5) descends and discharges the partition (5) in order to fill in water

13-A crashed ice making machine (1) as in claim 12, characterized by more than one pushing mechanism (C), each being realized by means of a pushing shaft (8) that extends into the partition (5) through an opening formed at the base portion of the partition (5) and skidded to the partition (5) opening over a sealing element (7) so as to rise and descend and by the ice dispensing mechanism (A) having a geared or screwed shaft carrier (9) driven by the driving mechanism (D) and whereon the pushing shafts (8) are fixed.

14-A crashed ice making machine (1) as in claim 13, characterized by a stopping mechanism that limits the forwards-backwards movement of the shaft carrier (9).

15-A refrigerator characterized by a freezing compartment, a crashed ice making machine (1) as in claim 1, placed into the freezing compartment, a control unit that controls the driving mechanism (D) of the crashed ice making machine (1) and the water filling mechanism filling the ice container (4) with water, and a crashed ice collection receptacle that is stationary or detachable, that can be accessed from inside or outside the refrigerator and wherein crashed ice pieces produced by the crashed ice making machine (1) are collected.

16-A crashed ice making machine (1) as in claim 2, characterized by the ice cutting mechanism (B) comprising an ice cutting blade (2) that is placed at the inlet portion of the ice container (4) and provides crashed ice by rotating and cutting the ice pushed out of the ice container (4).

17-A crashed ice making machine (1) as in claim 16, characterized by the ice cutting blade (2), the lower surface of which is realized so as to be seated onto the inlet of the ice container (4) in a flat manner and the upper surface of which is realized to be inclined (θ).

18-A crashed ice making machine (1) as in claim 17, characterized by a motor (13), the driving mechanism (D) comprising a transmission mechanism (11) that can be rotated by the motor (13) and that has at least one worm and at least one gear placed outside the partitions (5), more than one pushing mechanism (C) each driven by the transmission mechanism (11) so as to rise and descend in the ice container (4) and the ice cutting mechanism (B) driven by the transmission mechanism (11) so as to cut the ice pushed out of the ice container (4) by rotating.

19-A crashed ice making mechanism (1) as in claim 18, characterized by the driving mechanism (D) comprising the transmission mechanism (11) having a worm placed outside the partitions (5) so that the rotational axis (Z) thereof is parallel to the axis of the partitions (5) in the base-inlet direction.

20-A crashed ice making machine (1) as in claim 19, characterized by the ice cutting mechanism (B) that is connected to the end of the worm so as to pass over the inlet portions of the ice container (4) partitions (5) and that cuts the ice pushed out of the ice container (4) by rotating.