CN220541444U - Ice making box - Google Patents

Abstract

The utility model discloses an ice making box which comprises an ice making piece, an ice making mould and an ice removing piece, wherein a first supporting piece and a second supporting piece are arranged in the ice making piece, and the ice making mould comprises a first mould and a second mould; in a die closing state, the first die and the second die are closed to form an ice making cavity; in the mold opening state, the ice removing piece acts on the ice making mold to open the ice making cavity; in the ice-removing state, the ice-removing member presses a first mold, and the first mold is partially supported by the first supporting member in the ice-making member to generate integral deformation; or/and, the ice removing piece presses a second mould, and the second mould is locally supported by the second supporting piece in the ice making piece to generate integral deformation. The utility model has the advantages that: the whole mold opening and deicing process can be carried out by a user through the deicing piece, the direct contact is not needed to be carried out on the deicing mold, and the ice cubes are ensured not to be polluted by touching by hands.

Description

Ice making box

Technical Field

The utility model relates to ice making equipment, in particular to an ice making box.

Background

The ice cubes are often used for being placed in beverages or drinks, the conventional ice cubes are of cuboid structures, along with the improvement of people, the ice cubes in round, masonry-shaped and other shapes are required, the ice cubes cannot be formed by one die, the ice cubes are required to be spliced by two dies, an upper die and a lower die are generally adopted to be matched to form an ice making cavity, enough water is guaranteed in the ice making cavity, and then the ice cubes are placed into a refrigerator for freezing and forming.

The ice making mould with the structure needs to be opened firstly after ice making is completed, namely the upper mould and the lower mould are separated, the upper mould and the lower mould are provided with parts similar to handles, the upper mould and the lower mould are separated in a way that a user holds the handles for hard pulling, the force applied by the user is large, and ice cubes can be scattered when the upper mould and the lower mould are separated. And after breaking the upper and lower mould apart, still need twist the mould and break away from the ice-cube that will adhere to on the mould, above-mentioned in-process not only wastes time and energy, has the risk that lets the ice-cube scatter moreover, and the hand need hold upper and lower mould in addition when opening the mould and taking off ice, probably contacts the ice-cube for the ice-cube has contaminated risk.

Disclosure of Invention

The utility model aims to provide an ice making box, which can effectively solve the problem that hands are required to be in direct contact with a die in the existing ice making box for die opening and ice removing, and the risk of pollution to ice cubes exists.

In order to solve the technical problems, the utility model is realized by the following technical scheme:

the ice making box comprises an ice making piece and an ice making mould arranged in the ice making piece, and further comprises an ice removing piece, wherein a first supporting piece and a second supporting piece are arranged in the ice making piece, the ice making mould comprises a first mould and a second mould, and the first mould and the second mould are in a mould closing state, a mould opening state and an ice removing state;

In a die closing state, the first die and the second die are closed to form an ice making cavity;

in the mold opening state, the ice removing piece acts on the ice making mold to open the ice making cavity;

in the ice-removing state, the ice-removing member presses a first mold, and the first mold is partially supported by the first supporting member in the ice-making member to generate integral deformation; or/and, the ice removing piece presses a second mould, and the second mould is locally supported by the second supporting piece in the ice making piece to generate integral deformation.

In the ice making case, in the mold opening state, the ice removing member acts on an end surface of the second mold facing the first mold; in the ice-removing state, the first supporting piece is abutted with the end face, facing the second die, of the first die, and the second supporting piece is abutted with the end face, facing away from the first die, of the second die.

In the ice making box, the ice removing member is provided with an abutting part; in the ice-removing state, the abutting part presses the first die, and the end part of the ice-removing piece presses the second die; or in the ice-removing state, the abutting part presses the second die, and the end part of the ice-removing piece presses the first die.

In the ice making box, the first die is provided with a first opening, and the end part of the ice removing piece passes through the first opening and is abutted with the end face of the second die.

In the ice making case, a distance between the abutting portion and the end portion of the ice removing member is equal to or greater than a distance between the first mold and the second mold in the mold-opened state.

In the ice making case, the ice removing member passes through an edge of the first mold and abuts against an end surface of the second mold.

In the ice making box, the ice making piece comprises a box body and an upper cover covered on the box body, and a second opening for the ice removing piece to penetrate into the ice making piece is formed in the upper cover.

In the ice making case, the upper cover has a placement cavity in which the ice removing member is placed.

In the ice making box, a third opening for the ice removing member to penetrate into the ice making member is formed in the bottom of the ice making member.

In the ice making box, a guide post is arranged in the ice making piece, a fourth opening matched with the guide post is formed in the second die, and the guide post penetrates through the fourth opening.

In the ice making case, the first support is supported at an edge of the first mold; or/and, the second supporting piece is supported on the edge of the second die.

In the ice making box, the ice removing member comprises a rod body which is used for being abutted against the first die or the second die, the projection surface of the rod body is not overlapped with the projection surface of the first supporting member, and the projection surface of the rod body is not overlapped with the projection surface of the second supporting member.

In the above ice making case, the ice removing member includes a first ice removing member and a second ice removing member; the first ice removing member and the second ice removing member press an edge of the first mold; alternatively, the first and second de-icing members may press an edge of the second mold.

In the ice making case, the first and second ice removing members press the edge of the first mold, two first supporting members are provided, and the projected connecting lines of the two first supporting members on the first mold intersect with the projected connecting lines of the first and second ice removing members on the first mold.

In the ice making case, the first and second ice removing members press the edge of the second mold, two second supporting members are provided, and the projected connecting lines of the two second supporting members on the second mold intersect with the projected connecting lines of the first and second ice removing members on the second mold.

In the above ice making case, the cross section of the ice making mold is a polygon having at least four sides, and the first and second ice removing members are positioned at both ends of one diagonal line of the ice making mold.

In the ice making case, there are two first supporting members, and the two first supporting members are positioned at both ends of the other diagonal line of the ice making mold.

In the ice making case, there are two second supporting members, and the two second supporting members are positioned at both ends of the other diagonal line of the ice making mold.

In the ice making box, the first die and the second die are connected through elastic buckles or in interference fit to achieve a die closing state.

In the ice making box, a lower deformation space for enabling the second die to generate integral deformation is reserved between the end face of the second die and the bottom of the ice making piece.

In the ice making case, in the mold opening state, a distance between an end surface of the first mold facing the second mold and an end surface of the second mold facing the first mold is larger than a height of the ice making cavity.

In the ice making box, an ice pouring opening is formed in the side wall of the ice making piece, the ice pouring opening is communicated with the ice making cavity in the mold opening state, and ice cubes separated from the ice making cavity are separated from the ice making box from the ice pouring opening.

In the ice making box, an ice storage part is arranged below the ice making part, and an ice storage cavity for storing the ice making mould is arranged in the ice storage part.

In the above ice making case, the first and second supports are each provided on a side wall of the ice making member; the second support is closer to the center of the ice making member than the first support; alternatively, the first support is closer to the center of the ice making member than the second support.

In the ice making box, a containing cavity is formed in the ice making piece, the ice making die is arranged in the containing cavity, a plurality of first die cavities are formed in the first die, second die cavities corresponding to the first die cavities are formed in the second die, the first die and the second die are closed in a die clamping state, and the first die cavities and the second die cavities enclose the ice making cavity;

the ice removing piece is rod-shaped, an abutting part is arranged on the ice removing piece, the abutting part is a protruding block protruding out of the outer surface of the ice removing piece, and the number of the ice removing pieces is two;

the edge of the first die is provided with a first opening corresponding to the number of the ice removing pieces, and in the die opening state, the end part of the ice removing piece passes through the first opening and is in butt joint with the edge of the second die;

Two guide posts are arranged on the inner side wall of the accommodating cavity, and a fourth opening matched with the guide posts is formed in the edge of the second die;

the inner side wall of the accommodating cavity is also provided with two second supporting pieces, the two second supporting pieces and the two first supporting pieces are arranged along the diagonal line of the same ice making mould, and the two ice removing pieces are arranged along the other diagonal line of the ice making mould; the first supporting piece and the second supporting piece are arranged at intervals, and a die opening space is reserved in the die opening direction of the ice making die;

in an ice-removing state, the end part of the ice-removing piece presses the edge of the second die, and the second supporting piece is abutted with the end surface of the second die, which is opposite to the first die; the abutting part of the ice removing piece presses on a first die beside the first opening, the end part of the guide column is the first supporting piece and abuts against the end face of the first die, facing the second die; a lower deformation space for enabling the second die to generate integral deformation is reserved between the end face of the second die and the bottom of the ice making piece;

the side wall of the ice making piece is also provided with an ice pouring opening which is communicated with the ice making cavity in the mold opening state.

Compared with the prior art, the utility model has the advantages that:

the ice making mould in the ice making piece is opened and iced through the icebreaking piece, so that the problem that the existing ice making box needs hands to be in direct contact with the mould for opening and icebreaking and the risk of polluting ice cubes is solved. The ice removing piece acts on the ice making mould to open the ice making cavity, so that the direct contact of a hand with the mould in the mould opening state is avoided, and the ice removing piece can act on the first mould or/and the second mould to enable the first mould and the second mould to generate relative movement, so that the mould opening purpose is realized; in the ice removing state, the first mould is locally supported by the first supporting piece, and when the ice removing piece applies pressure to the first mould, the first mould is integrally deformed under the mutual matching of the ice removing piece and the first supporting piece, namely the whole first mould is deformed, so that ice cubes adhered to the first mould are separated from the first mould; the ice removing piece can only act on the second mould, the second mould is locally supported by the second supporting piece, when the ice removing piece is pressed on the second mould, the second mould is integrally deformed, namely the whole second mould is deformed, and ice cubes adhered on the second mould can be separated from the second mould; of course, the ice removing member may be applied to the first mold and the second mold to deform the first mold and the second mold integrally, so that ice cubes adhered to the first mold and the second mold are removed. The whole mould opening and deicing process can be carried out on the ice making mould by a user by using the deicing piece in the ice making piece, the ice making mould does not need to be touched directly, the ice making mould does not need to be taken out from the ice making piece, and the ice cubes are ensured not to be polluted by touching by hands.

Further, in the mold opening state, the ice removing member acts on the end face of the second mold facing the first mold; in the ice-removing state, the first supporting piece is abutted with the end face, facing the second die, of the first die, and the second supporting piece is abutted with the end face, facing away from the first die, of the second die. In the mold opening state, the ice removing piece acts on the end face of the second mold facing the first mold to apply force to the second mold, so that the second mold is separated from the first mold, and mold opening is realized; in the ice-removing state, the supporting positions of the first supporting piece and the first die and the supporting positions of the second supporting piece and the second die are also used, so that the ice-removing piece can realize the die opening and ice removing of the ice-making die only by applying force to the ice-making die from one direction, and the operation steps of a user are simplified.

Further, an abutting part is arranged on the deicing piece; in the ice-removing state, the abutting part presses the first die, and the end part of the ice-removing piece presses the second die; or in the ice-removing state, the abutting part presses the second die, and the end part of the ice-removing piece presses the first die. The abutting part is arranged on the ice removing piece and matched with the end part of the ice removing piece, the abutting part and the end part respectively press the first die and the second die, so that the first die and the second die can generate integral deformation in an ice removing state, and the ice blocks can be demoulded.

Further, the first die is provided with a first opening, and the end part of the ice removing piece passes through the first opening and is abutted with the end surface of the second die. The first opening is arranged, and when the ice removing piece drives the second die to separate relative to the first die, the first die does not block the movement of the ice removing piece.

Further, a distance between the abutting portion and the end portion of the ice removing member is equal to or greater than a distance between the first mold and the second mold in the mold opening state. When the conditions are met, the abutting part and the end part can be contacted with the corresponding first mould and the second mould simultaneously, so that the first mould and the second mould are deformed integrally at the same time, and demoulding is carried out together; or, one die can be selected to be integrally deformed according to the characteristics of the dies, and the other die is integrally deformed again, so that the deformation amounts of the two dies are kept consistent, and the ice removing is smoothly carried out. In addition, if the above conditions are not met, the ice making mold is not opened, the first mold enters an ice removing state, and the second mold may not be completely ice removed, that is, the end of the ice removing member may not be extruded by the second mold, so that the second mold is integrally deformed.

Further, the deicing member passes through the edge of the first mold and abuts against the end face of the second mold. The structure of another first mould utilizes the edge that the piece that takes off ice can be through the terminal surface butt with the second mould from first mould, promotes the second mould and realizes the die sinking to can not influence the state of first mould, also avoid taking off ice and first mould contact and produce the resistance, realize more smooth and easy die sinking.

Further, the ice making piece comprises a box body and an upper cover covered on the box body, and a second opening for the ice removing piece to penetrate into the ice making piece is formed in the upper cover. Foreign matters or dust can be prevented from contacting the ice making mould in the ice making or mould opening and ice removing state through the upper cover, and the second opening is formed in the upper cover, so that the upper cover is prevented from being blocked when the ice removing piece is subjected to mould opening or ice removing.

Further, the upper cover has a placement cavity in which the ice removing member is placed. When the ice removing member is not in use, a storage space is provided to prevent the ice removing member from being lost.

Further, a third opening for the ice removing member to penetrate into the ice making member is formed in the bottom of the ice making member. In another mode that the ice removing piece enters the ice making piece, the ice making piece enters the ice making piece from the third opening at the bottom of the ice making piece, the ice making die is controlled to complete die opening and ice removing, and at the moment, a user can hold the ice making piece to control the ice making die to open die and remove ice. The ice removing piece penetrates from the bottom of the ice making piece and is abutted with the ice making mould. In the mold closing state, the ice removing piece can support the ice making mold. In the mold opening state, the ice removing piece acts on the ice making mold, and the ice making cavity is opened, so that the first mold and the second mold move relatively. In the ice removing state, the ice removing piece is matched with the first supporting piece to enable the first die to generate integral deformation or/and the ice removing piece is matched with the second supporting piece to enable the second die to generate integral deformation.

Further, a guide column is arranged in the ice making piece, a fourth opening matched with the guide column is formed in the second die, and the guide column penetrates through the fourth opening. The guide post is matched with the fourth hole, so that the movement of the second die is guided in the die opening state, and the ice removing piece can be accurately aligned with the second die to apply force in the ice removing state. The first support may be a guide post that abuts the first die through the fourth aperture of the second die. In the open state, the second mold is away from the first mold along the guide post.

Further, the first support is supported at the edge of the first mold; or/and, the second support member is supported at the edge of the second mold. The support piece supports the edges of the corresponding die, and when the die is pressed by matching with the ice removing piece, the die can be deformed integrally to the greatest extent, so that all ice cubes can be removed from the die.

Further, the deicing piece comprises a rod body which is used for being abutted against the first die or the second die, the projection surface of the rod body is not overlapped with the projection surface of the first supporting piece, and the projection surface of the rod body is not overlapped with the projection surface of the second supporting piece. The supporting piece and the rod body are prevented from being in the same straight line, and the force of the rod body acting on the die generates moment relative to the supporting piece, so that the die is better deformed integrally.

Further, the ice removing member includes a first ice removing member and a second ice removing member; the first ice removing piece and the second ice removing piece are pressed on the edge of the first die; alternatively, both the first and second de-icing members may press against the edge of the second mould. When the ice removing piece is provided with two molds, the force points are dispersed, so that the molds can be better deformed integrally, and enough deformation amount is provided to enable ice cubes to be separated from the molds.

Further, the first deicing member and the second deicing member press the edge of the first mold, two first supporting members are arranged, and the projection connecting line of the two first supporting members on the first mold is intersected with the projection connecting line of the first deicing member and the second deicing member on the first mold. That is, the projection line of the first mold of the first ice removing member and the projection line of the second ice removing member on the first mold are not parallel to the projection line of the two first supporting members on the first mold. If the first and second ice removing pieces are parallel, the first and second ice removing pieces are pressed on one sides of the projections of the two first supporting pieces, so that the first mold is stressed unevenly and ice is difficult to remove. Therefore, when the projected connecting line on the first mould of the first supporting piece is intersected with the projected connecting lines of the first ice removing piece and the second ice removing piece on the first mould, larger moment can be obtained when pressure is applied, the force applied by the integral deformation of the first mould is reduced, and the purpose of saving labor is achieved.

Further, the first ice removing piece and the second ice removing piece press the edge of the second mould, two second supporting pieces are arranged, and the projection connecting line of the two second supporting pieces on the second mould is intersected with the projection connecting line of the first ice removing piece and the second ice removing piece on the second mould. Similarly, when the projection connecting lines of the two second supporting pieces on the second mould are intersected with the projection connecting lines of the first ice removing piece and the second ice removing piece on the second mould, larger moment can be obtained when pressure is applied, the force required to be applied for the second mould to generate integral deformation is reduced, and the purpose of saving labor is achieved.

Further, the cross section of the ice making mold is a polygon with at least four sides, and the first ice removing member and the second ice removing member are positioned at two ends of one diagonal line of the ice making mold. The distance between the two ice removing pieces is prolonged as much as possible, the area of the ice removing piece, which is influenced by the pressure of the ice removing pieces on the ice making mould, is enlarged, and the purpose of ice removing is better realized.

Further, there are two first supporting members, and two first supporting members are located at two ends of a diagonal line of the ice making mold, so that a larger moment is obtained to enable the first mold to generate integral deformation.

Further, two second supporting pieces are arranged at two ends of a diagonal line of the ice making mould, so that larger moment is obtained to enable the second mould to generate integral deformation.

Further, the first die and the second die are connected through elastic buckles or in interference fit to achieve a die closing state. Through elasticity buckle or interference fit connection, utilize the piece that takes off ice can destroy the connected state relatively easily to let the user operate when taking off ice the mould simpler, and first mould and second mould also are difficult to separate under the compound die state.

Further, a lower deformation space for the second mold to generate integral deformation is reserved between the end face of the second mold and the bottom of the ice making piece. The second mould has enough space to generate integral deformation or maximum deformation, and the ice blocks are ejected from the second mould.

Further, in the mold opening state, a distance between the end face of the first mold facing the second mold and the end face of the second mold facing the first mold is larger than the height of the ice making cavity. And in the mold opening state, enough space is reserved between the first mold and the second mold to enable the ice cubes after ice removal to be separated from the ice making mold.

Further, the side wall of the ice making piece is provided with an ice pouring opening, the ice pouring opening is communicated with the ice making cavity in the open mode, and ice cubes separated from the ice making cavity are separated from the ice making box from the ice pouring opening. The ice blocks are positioned between the first die and the second die after the ice is removed, an operator holds the ice making box to enable the ice pouring opening to face the vessel, and the ice blocks after the ice removing state can be directly led into the vessel of a user through the ice pouring opening, so that the user can not touch the ice blocks from ice making and ice removing to ice pouring, and the sanitation of the ice blocks is ensured.

Further, the ice storage part is arranged below the ice making part, and an ice storage cavity for storing the ice making mould is arranged in the ice storage part. The ice making member may be stacked on the ice storage member. The ice storage piece is equivalent to a vessel, and ice cubes can be poured into the ice storage piece after ice removal for users to use according to the needs. The ice making box of the scheme can realize that a plurality of ice making grid molds can make ice together. For example, a plurality of ice-making molds filled with water are placed in the ice-storing member, one ice-making mold filled with water is placed in the ice-making member, and then the ice-making member is stacked on the ice-storing member and placed in a refrigerator while ice is made.

Further, the first supporting piece and the second supporting piece are arranged on the side wall of the ice making piece; the second support member is closer to the center of the ice making member than the first support member; alternatively, the first support is closer to the center of the ice making member than the second support. The two supporting pieces are arranged in the front-back direction along the side wall of the ice making piece towards the center of the ice making piece, so that interference between the first die and the second supporting piece or interference between the second die and the first supporting piece can be avoided.

Drawings

FIG. 1 is a perspective view of a first embodiment of an ice making housing according to the present utility model;

FIG. 2 is an exploded view of one embodiment of an ice making housing according to the present utility model;

FIG. 3 is a cross-sectional view of one embodiment of an ice making housing according to the present utility model;

FIG. 4 is a schematic view showing the cooperation structure of an ice making member, an ice making mold and an ice removing member in an embodiment of an ice making case according to the present utility model;

FIG. 5 is an exploded view of an ice-making mold in an ice-making housing according to the present utility model;

FIG. 6 is an exploded view of a second embodiment of an ice-making mold in an ice-making housing according to the present utility model;

FIG. 7 is a perspective view of an ice-making member of a first embodiment of an ice-making housing according to the present utility model;

FIG. 8 is an enlarged view of a portion of FIG. 7 at A;

fig. 9 is a perspective view of an ice-removing member in an ice-making housing according to the present utility model;

FIG. 10 is a cross-sectional view showing an ice-removing state in a first embodiment of an ice-making housing according to the present utility model;

fig. 11 is a cross-sectional view of a second embodiment of an ice-making housing according to the present utility model.

The reference numerals are:

the ice making device 100, the receiving chamber 101, the first support 110, the second support 120, the case 130, the upper cover 140, the placing chamber 141, the second opening 150, the lower cover 160, the third opening 161, the guide post 170, the lower deformation space 180, and the ice pouring opening 190;

ice making mold 200, first mold 210, first mold cavity 211, first opening 212, second mold 220, second mold cavity 221, fourth opening 222, ice making cavity 230;

the ice removing member 300, the abutting portion 310, the rod body 320, the first ice removing member 330, the second ice removing member 340;

Ice storage 400, ice storage cavity 410.

Detailed Description

Reference will now be made in detail to embodiments of the present utility model, examples of which are illustrated in the accompanying drawings. The embodiments described below by referring to the drawings are illustrative and intended to explain the present utility model and should not be construed as limiting the utility model.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the drawings are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the device or element in question must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present utility model, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed; may be mechanically connected, may be electrically connected or may be in communication with each other; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

Embodiment one:

as shown in fig. 1 to 11, an ice making case includes an ice making member 100 and an ice making mold 200 provided in the ice making member 100, the ice making case further includes an ice removing member 300, a first support 110 and a second support 120 are provided in the ice making member 100, the ice making mold 200 includes a first mold 210 and a second mold 220, and the first mold 210 and the second mold 220 have a mold-closed state, a mold-opened state, and an ice removing state;

in the mold-closed state, the first mold 210 and the second mold 220 are closed to form an ice making cavity 230;

In the opened state, the ice removing member 300 acts on the ice making mold 200, opening the ice making cavity 230;

in the ice-releasing state, the ice-releasing member 300 presses the first mold 210, and the first mold 210 is partially supported by the first support 110 in the ice-making member 100, resulting in an overall deformation; alternatively or/and, the ice removing member 300 presses the second mold 220, and the second mold 220 is partially supported by the second support 120 in the ice making member 100, thereby generating an overall deformation.

The ice-making mold 200 in the ice-making member 100 is opened and de-iced by the de-icing member 300, so that the problem that the existing ice-making box is opened and de-iced, and a hand is required to directly contact the mold, so that the risk of polluting ice cubes exists is solved. The ice making cavity 230 is opened by acting the ice removing piece 300 on the ice making mould 200, so that the direct contact of hands with the mould in the mould opening state is avoided, and the ice removing piece 300 can act on the first mould 210 or/and the second mould 220 to enable the first mould 210 and the second mould 220 to generate relative movement, so that the mould opening purpose is realized; in the ice removing state, the first mold 210 is partially supported by the first supporting member 110, and when the ice removing member 300 applies pressure to the first mold 210, the first mold 210 is integrally deformed under the mutual cooperation of the ice removing member 300 and the first supporting member 110, that is, the whole first mold 210 is deformed, so that ice cubes adhered to the first mold 210 are separated from the first mold 210; the ice removing member 300 may only act on the second mold 220, the second mold 220 is partially supported by the second supporting member 120, and when the ice removing member 300 is pressed on the second mold 220, the second mold 220 is integrally deformed, that is, the entire second mold 220 is deformed, so that ice cubes adhered on the second mold 220 can be separated from the second mold 220; of course, the ice removing member 300 may be applied to the first mold 210 and the second mold 220 to deform the two integrally, thereby removing the ice cubes adhered to the first mold 210 and the second mold 220. Throughout the mold opening and de-icing process, the user can operate using the de-icing member 300 without touching the ice-making mold 200 directly, ensuring that the ice cubes are not contaminated by touching with his hands.

Referring to fig. 1 to 11, an ice making case according to an embodiment of the present utility model includes an ice making member 100 and an ice making mold 200 provided in the ice making member 100, the ice making mold 200 having a cross-sectional shape corresponding to that of the ice making member 100, a receiving cavity 101 provided in the ice making member 100, the receiving cavity 101 may be provided in a vertically opened form, or may be provided in a top or bottom opened form and provided with a cover body closing the opening, and the ice making mold 200 is provided in the receiving cavity 101, so that the ice making mold 200 is slightly smaller in size than the ice making member 100, and so-called the ice making mold 200 is placed in the ice making member 100, including the ice making mold 200 being wholly or partially positioned in the ice making member 100. The ice-making member 100 is generally made of hard materials, and needs to protect and make the ice-making mold 200, while the ice-making mold 200 may be made of deformable and supporting materials, and the ice-making mold 200 needs to be installed in the ice-making member 100 and also needs to be deformed to facilitate demolding, and the materials of the ice-making mold 200 may be consistent with those of the existing spherical ice-making mold 200, and the materials of the ice-making mold 200 include, but are not limited to, PP materials and TPR materials. The overall deformation of the ice making mold 200 includes the deformation of the entire ice making mold 200. Only the plurality of ice making cavities of the ice making mold 200 for containing water are deformed within the meaning of being integrally deformed by the ice making mold 200.

The utility model is mainly used for manufacturing spherical, masonry, water drop, conical, square and other shaped ice cubes. This embodiment will be described taking the example of making spherical ice cubes.

As shown in fig. 5 and 6, the ice making mold 200 includes a first mold 210 and a second mold 220, each of which is provided with a cavity facing the other mold, and the two cavities are combined to form an ice making cavity 230, and the ice making cavity 230 is the shape of the last ice block to be made, and since spherical ice blocks are to be made in this embodiment, hemispherical cavities are provided on the first mold 210 and the second mold 220, respectively.

The ice making housing further includes an ice removing member 300, and the ice removing member 300 may be separately provided from the ice making member 100 and the ice making mold 200, or the ice removing member 300 may be movably provided on the ice making member 100 or the ice making mold 200. The first support member 110 and the second support member 120 are disposed in the ice making member 100, and the first support member 110 and the second support member 120 may be fixed on the inner side wall of the ice making member 100 by bonding or clamping, or the first support member 110 and the second support member 120 may be integrally manufactured with the ice making member 100. The end surface of the first support 110 for providing support is at a different height than the end surface of the second support 120 for providing support. The first and second supports 110 and 120 may be bosses extending inward from the sidewalls of the ice making member 100. Or the first support 110 and the second support 120 may be support columns of different heights. The first support 110 and the second support 120 may be integrally connected to each other in view of saving space within the ice making device 100.

The first mold 210 and the second mold 220 have a mold-closed state, a mold-open state, and an ice-removing state.

In the closed state, the first mold 210 and the second mold 220 are closed to form the ice making cavity 230, and the first mold 210 and the second mold 220 are generally placed up and down, and in fig. 5, the first mold 210 at the top and the second mold 220 at the bottom are described as an example. The second mold 220 is provided with a water tank with an upward opening, the bottom surface of the water tank is provided with a plurality of second mold cavities 221 which are recessed downwards, the bottom surface of the first mold 210 is provided with a plurality of first mold cavities 211 which are recessed upwards, the first mold cavities 211 and the corresponding second mold cavities 221 are closed to form an ice making cavity 230, and in this embodiment, a plurality of ice making cavities 230 are formed after the first mold 210 and the second mold 220 are closed. The depth of the water tank is greater than the height of the first mold cavities 211, so that after the water tank is filled with water, the first mold 210 is placed in the water tank, the water in the water tank fills the first mold cavities 211, overflow holes are formed in the top of each first mold cavity 211, and excessive water overflows from the overflow holes, so that the ice making cavities 230 are in a full water state, and complete spherical ice cubes are obtained after freezing. In the present embodiment, since the first mold 210 is positioned above and the second mold 220 is positioned below, the entire ice-making mold 200 is supported by the first support 110, and the relative positions of the ice-making mold 200 and the ice-making member 100 are fixed in the closed state.

The first mold 210 and the second mold 220 may be closed in various manners, and may be relatively fixed in an elastic snap-fit manner or an interference fit manner. If elastic buckles are adopted, a bulge can be arranged on one die, a pit is correspondingly arranged on the other die, and when the first die 210 and the second die 220 are required to be separated, the bulge can be separated from the pit only by deformation of the die; when the first mold 210 and the second mold 220 are not subjected to external force, the first mold 210 and the second mold 220 can be held relatively fixed, and thus, the fixing method is also a preferable fixing method.

In the opened state, the ice removing member 300 acts on the ice making mold 200, opening the ice making cavity 230. The ice removing member 300 is applied to the ice making mold 200, the first mold 210, the second mold 220, or both the first mold 210 and the second mold 220, and the purpose of the ice removing member 300 in the opened state is to separate the first mold 210 and the second mold 220 from each other. If the first mold 210 and the second mold 220 are relatively fixed, such as trigger type buckles, the ice removing member 300 acts on the trigger type buckles to unlock the buckles, so that the first mold 210 and the second mold 220 are separated, and the purpose of opening the ice making cavity 230 is achieved.

In the ice removing state, the ice removing member 300 presses the first mold 210, the first mold 210 is partially supported by the first supporting member 110 in the ice making member 100 to generate overall deformation, the first mold 210 is pressed by the ice removing member 300, and the first mold 210 is partially supported by the first supporting member 110, so that the first mold 210 can more conveniently generate overall deformation; the first mold 210 after the integral deformation is separated from the ice cubes retained in the first mold cavity 211, thereby achieving the ice removing effect; the ice removing member 300 may also press the second mold 220, and the second mold 220 is partially supported by the second support 120 in the ice making member 100 to be integrally deformed, which is the same purpose as the ice making member 100 acts on the first mold 210. The ice cubes are separated from the first mold 210 and the second mold 220 by the ice removing member 300, and the ice removing is completed.

In the above process, only in the mold closing state, the user may touch the ice making mold 200 with his hand, but since water is still present in the ice making mold 200, sterilization can be performed conveniently. In both the opened state and the ice-removing state, the first mold 210 and the second mold 220 are operated by the ice-removing member 300, and the user cannot directly contact the ice-removing mold, so that the user's hand can be prevented from directly contacting the ice cubes, and the sanitation standard is improved.

Further, in the present embodiment, the mold opening and the ice removing will be implemented in such a manner that the ice removing member 300 is inserted into the ice making member 100 from the top. Specific:

in the mold-opened state, the ice removing member 300 acts on the end surface of the second mold 220 facing the first mold 210, and since the first mold 210 is above the second mold 220, in this state, the ice removing member 300 acts on the end surface of the second mold 220 facing the first mold 210, that is, on the top end surface of the second mold 220, the following manner may be adopted: one way is to open the first opening 212 in the first mold 210, as shown in fig. 6, the first opening 212 may be a closed cross section, as shown in fig. 5, or the first opening 212 may be an open cross section, so that the bottom end of the ice removing member 300 passes through the first opening 212 to abut against the upper end surface of the second mold 220, and thus, the ice removing member 300 is forced on the second mold 220, so that the first mold 210 and the second mold 220 can be separated, and the mold opening purpose is achieved. The other is to let the second mold 220 extend beyond the first mold 210 from the periphery of the first mold 210, and let the ice removing member 300 abut against the end surface of the second mold 220 from the edge of the first mold 210 to realize mold opening. In this structure, a fourth hole 222 is formed in the second mold 220 so that the first support 110 can pass through the fourth hole 222 to support the first mold 210.

In the ice-removing state, the first supporting member 110 abuts against the end face of the first mold 210 facing the second mold 220, that is, the first supporting member 110 abuts against the bottom surface of the first mold 210, so as to prevent the first mold 210 from moving downwards; the second support 120 abuts against the end surface of the second mold 220 facing away from the first mold 210, that is, the second support 120 abuts against the bottom surface of the second mold 220. Since the ice removing member 300 applies force to the first mold 210 and the second mold 220 from the top down, the first mold 210 receives the downward force of the ice removing member 300 and the upward force of the first supporting member 110, thereby integrally deforming the first mold 210; and for the second mold 220, is also integrally deformed with the hair.

Still further, in the ice removing state, the ice removing member 300 may apply force to the first mold 210 and the second mold 220, respectively, for example, the ice removing member 300 may be used to separate the first mold 210 from the second mold 220, then the ice removing member 300 is pulled out and pressed onto the first mold 210, and the ice removing is performed on the first mold 210. Because the icebreaker 300 does not have an abutting effect on the first mold 210 when passing through the first aperture 212 or passing from the edge of the first mold 210. The ice removing member 300 does not simultaneously act on the first mold 210 when the second mold 220 is pressed to be integrally deformed.

In addition, the manner of pushing the ice removing member 300 to remove ice from the first mold 210 and the second mold 220 may be selected to be described from the viewpoint of efficiency, in which the ice removing member 300 is pushed to remove ice from the first mold 210 and the second mold 220:

the ice removing member 300 is provided with an abutting portion 310, and in the ice removing state, one of the abutting portion 310 and the end portion of the ice removing member 300 presses the first mold 210, and the other presses the second mold 220. In the present embodiment, the first mold 210 is pressed by the abutting portion 310, and the second mold 220 is pressed by the end portion of the ice removing member 300. The ice removing member 300 includes a rod 320, a handle may be further disposed at the top of the rod 320 to increase the contact area with the palm, so that a user may operate the ice removing member 300 more conveniently, and the abutting portion 310 may extend beyond the surface of the rod 320, for example, as shown in fig. 9, a boss may be disposed on the outer surface of the rod 320 to form the abutting portion 310, or the rod 320 may be partially formed into a truncated cone shape with a smaller bottom and a larger top along the direction perpendicular to the insertion direction. In this way, after the bottom end of the ice removing member 300 passes through or passes over the first mold 210, the bottom end of the ice removing member 300 is abutted against the top surface of the second mold 220, the second mold 220 is separated from the first mold 210 to realize mold opening, and then the ice removing member 300 is pushed continuously, the bottom end of the ice removing member 300 is pressed on the second mold 220, so that the second mold 220 is integrally deformed, the abutting part 310 on the ice removing member 300 is also contacted with the first mold 210, the first mold 210 is pressed, and the first mold 210 is integrally deformed.

In addition to the above-mentioned structure of the deicing member 300, the distance between the abutting portion 310 and the end portion of the deicing member 300 is greater than or equal to the distance between the first mold 210 and the second mold 220 in the mold opening state, so that the end portion of the deicing member 300 can be ensured to be in contact with the second mold 220 to be demolded, the second mold 220 is integrally deformed first, the first mold 210 is integrally deformed later, or the first mold 210 and the second mold 220 are integrally deformed together, and deicing is ensured to be performed after the mold opening state is completed.

As shown in fig. 1 and 2, for the ice making member 100 in this embodiment, a top cover opening structure may be adopted, so that the ice making mold 200 can be conveniently taken out of and put into the ice making member 100, the ice making member 100 includes a box body 130 and an upper cover 140 covering the box body 130, that is, the box body 130 is a structure with an opening at the top surface, and the opening at the top is closed by the upper cover 140, so that foreign matters and the like are prevented from entering the ice making member 100 during the process of ice making, and also during mold opening and ice removing, and the sanitation level in the ice making member 100 is improved. However, in order to facilitate the mold opening and the ice removing of the ice removing member 300, the second opening 150 for inserting the ice removing member 300 into the ice making member 100 is formed in the upper cover 140, and the shape of the second opening 150 is adapted to the shape of the ice removing member 300, and if the ice removing member 300 is provided with the abutting portion 310, the abutting portion 310 needs to be allowed to enter into the ice making member 100.

As shown in fig. 1, further, in order to facilitate storage of the ice removing member 300 when the ice removing member 300 is not in use, a storage chamber 141 in which the ice removing member 300 is placed is opened on the upper cover 140. Protrusions may be provided on the inner sidewall of the placement cavity 141 to prevent the ice removing member 300 from being separated from the placement cavity 141, and at the same time, the user does not need much force to take out the ice removing member 300 due to the small protrusions.

As shown in fig. 10, in the above embodiment, in the mold opening state, the second mold 220 is to move downward relative to the first mold 210, in order to prevent the second mold 220 from being blocked in the ice making member 100 during mold opening, the guide post 170 is disposed in the ice making member 100, the fourth opening 222 that cooperates with the guide post 170 is disposed on the second mold 220, and the movement track of the second mold 220 during mold opening is limited by cooperation of the guide post 170 and the fourth opening 222. And the top surface of the guide post 170 may extend to the bottom surface of the first mold 210, so that the top end of the guide post 170 becomes the first support 110 to support the first mold 210.

As shown in fig. 7 and 8, the second support 120 is provided below the first support 110, and preferably, the first support 110 and the second support 120 are aligned on the same vertical line, so that the structure of the ice removing member 300 can be simplified, and the ice removing member 300 can be provided in a long straight shape. Further, the second support 120 is closer to the center of the ice making member 100 with respect to the first support 110, or the first support 110 is closer to the center of the ice making member 100 with respect to the second support 120, that is, in a direction toward the center of the side wall of the ice making member 100, and the two supports are disposed in front and back to avoid interference between the first mold 210 and the second support 120 or interference between the second mold 220 and the first support 110.

In addition, the first support 110 may be supported at an edge of the first mold 210; alternatively, the second supporting member 120 is supported on the edge of the second mold 220, so that the ice removing member 300 can be deformed integrally with the mold with a small force applied thereto, and it is preferable that the first supporting member 110 is supported on the edge of the first mold 210 and the second supporting member 120 is supported on the edge of the second mold 220, so that the ice removing can be performed with a small force applied to both the first mold 210 and the second mold 220. Similarly, the ice removing member 300 can apply pressure to the edge of the corresponding mold to achieve the purpose of removing ice with a small force. Of course, both the ice removing member 300 and the supporting member may act on the edge of the mold to achieve the best effect.

Since the first supporting member 110 and the second supporting member 120 are disposed on the inner sidewall of the ice making member 100, the first supporting member 110 and the second supporting member 120 are disposed on both sides, and when the ice removing member 300 presses the first mold 210 and the second mold 220, the balance between the first mold 210 and the second mold 220 can be better maintained, and the first mold 210 and the second mold 220 are prevented from being turned over, so that the ice removing member 300 slides out of the corresponding molds and ice removing cannot be completed.

At this time, there may be only one ice removing member 300, but the projection surface of the rod 320 of the ice removing member 300 is not coincident with the projection surface of the first supporting member 110, and the projection surface of the rod 320 of the ice removing member 300 is not coincident with the projection surface of the second supporting member 120, so that when the ice removing member 300 acts on the first mold 210 and the second mold 220, the downward acting force of the ice removing member 300 to the mold and the upward acting force of the supporting member to the mold are not in the same straight line, and after the mold receives the acting forces in two different directions and not in the same straight line, the mold will generate distortion, so that the overall deformation is easier to occur.

On the basis of the above-described embodiments, the support member, the ice removing member 300, and the disposition state of the mold in the ice removing state will be specifically described taking the cross section of the ice making mold 200 as a rectangle. In this structure, two structural forms of the first supporting member 110 and the second supporting member 120 are adopted, which is more favorable for keeping the stability of the first mold 210 and the second mold 220 in the ice-removing state, and meanwhile, the ice-removing member 300 also has two first ice-removing member 330 and second ice-removing member 340, respectively, and the first ice-removing member 330 and the second ice-removing member 340 have the same structure.

The specific structure of the first and second ice removing members 330 and 340 may refer to the structure of the ice removing member 300 described above. The end of the first ice removing member 330 and the end of the second ice removing member 340 are pressed against the edge of the second mold 220, and the abutting portion 310 of the first ice removing member 330 and the abutting portion 310 of the second ice removing member 340 are pressed against the edge of the first mold 210.

The line of projection of the two first supporting members 110 on the first mold 210 intersects the line of projection of the first ice removing member 330 and the second ice removing member 340 on the first mold 210, so as to avoid that the force exerted by the ice removing member 300 on the first mold 210 and the force moment exerted by the supporting members on the first mold 210 are too short in parallel, and likewise, the line of projection of the two second supporting members 120 on the second mold 220 intersects the line of projection of the first ice removing member 330 and the second ice removing member 340 on the second mold 220.

Still further, the first and second ice removing members 330 and 340 are disposed at both ends of the diagonal line of the ice making mold 200, and the two first and second supporting members 110 and 120 are disposed at both ends of the other diagonal line of the ice making mold 200. Thus, when the first and second ice removing members 330 and 340 are simultaneously pressed downward, the first and second molds 210 and 220 can be integrally deformed with a small pressure, thereby achieving the purpose of ice removal with a small force.

Of course, the ice-making mold 200 may be one of polygons having at least four sides, and the installation state of the support, the ice-removing member 300, and the mold in the ice-removing state is consistent with the above-described installation state principle.

In the above embodiment, since the second mold 220 is integrally deformed due to the ice removing member 300 after being separated from the first mold 210 by the downward movement, a lower deformation space 180 for deforming the second mold 220 is left between the end surface of the second mold 220 and the bottom of the ice making member 100, so as to prevent the bottom surface of the ice making member 100 from obstructing the deformation of the second mold 220, and thus the second mold 220 cannot completely remove ice.

Of course, in the opened state, the second mold 220 needs to be moved a sufficient distance with respect to the first mold 210 to ensure that the ice cubes after ice removal are completely separated from the ice making mold 200, and the distance between the end surface of the first mold 210 facing the second mold 220 and the end surface of the second mold 220 facing the first mold 210 is greater than the height of the ice making cavity 230.

In addition, the side wall of the ice making piece 100 is provided with the ice pouring opening 190, the ice pouring opening 190 is communicated with the ice making cavity 230 in the mold opening state, and ice cubes separated from the ice making cavity 230 are separated from the ice making box from the ice pouring opening 190, so that the ice cubes directly enter the vessel, the whole process is free from touching by hands, and ice is not required to be shoveled by an ice shovel, so that the ice making device is convenient and sanitary.

The ice storage member 400 may be further disposed below the ice making member 100, and the ice storage chamber 410 of the ice making mold 200 at the vehicle storage position is disposed in the ice storage member 400, so that two ice making molds 200 can be simultaneously disposed in the whole ice making box, ice making efficiency is improved, and ice storage capacity is also improved.

As shown in fig. 1 to 3 and 10, in the ice making case of the present embodiment, when in use, the second mold 220 is filled with water, the first mold 210 and the second mold 220 are closed, the whole ice making cavity 230 is filled with water, the ice making mold 200 behind the first mold is placed into the ice making member 100, and the first support member 110 supports the first mold 210, so as to keep the ice making mold 200 and the ice making member 100 relatively stationary. The upper cover 140 of the ice making member 100 is covered to prevent foreign matters from entering the ice making member 100, the ice making box is put into a refrigerator for freezing, when ice is required to be taken, the ice removing member 300 is operated, the end part of the ice removing member 300 sequentially passes through the second opening 150 and the first opening 212 and is abutted with the top surface of the second mold 220, the force is continuously applied to the ice removing member 300, the ice removing member 300 separates the second mold 220 from the first mold 210, the second mold 220 slides downwards along the guide post 170, and finally the second mold 220 is abutted by the second support 120 to stop moving, so that the mold opening is completed. Then, the force is continuously applied to the ice removing member 300, the bottom end of the ice removing member 300 is applied to the second mold 220, the second mold 220 is also supported by the second support member 120, and since the downward force applied by the ice removing member 300 and the upward force applied by the second support member 120 to the second mold 220 are not in the same straight line, the second mold 220 is twisted to generate integral deformation, the ice cubes adhered to the second mold 220 are separated from the second mold 220, the abutting portion 310 of the ice removing member 300 is applied to the first mold 210, and the integral deformation is generated by cooperation with the first support member 110, the ice cubes adhered to the first mold 210 are removed, thereby completing the ice removing. At this time, the ice cubes will remain in the space enclosed by the first mold 210, the second mold 220 and the ice making member 100. When ice is needed, the ice pouring opening 190 is opened, and ice cubes are directly poured into the vessel from the ice pouring opening 190 for use. According to the ice making box, after the ice making piece 100 is placed from the ice making die 200, a user can not directly touch the ice making die 200 any more, so that pollution to ice cubes in the ice making die is avoided, and the sanitation of ice use is ensured.

Embodiment two:

as shown in fig. 11, the first embodiment is different in that the second mold 220 is above and the first mold 210 is below in the first embodiment, and the structure of the first mold 210 is the same as that of the second mold 220 in the first embodiment, and the structure of the second mold 220 is the same as that of the first mold 210 in the first embodiment. The ice removing member 300 is inserted into the ice making member 100 from the bottom of the ice making member 100 to achieve a mold-opened and ice-removed state. In this exemplary embodiment, the top surface of the ice making member 100 is in a closed state, the ice making member 100 includes a case 130 and a lower cover 160, and a third opening 161 is provided in the lower cover 160 to allow the ice removing member 300 to be inserted into the receiving cavity 101.

When the mold opening is required, the ice making member 100 is inserted into the fifth opening, then the ice making member 100 is held, the bottom end of the ice removing member 300 is pushed against the table surface, and the ice making member 100 is forced downward, so that the mold opening and the ice removing are completed. Because the user's hand of the ice making case of this structure can act on the top surface of the ice making member 100 to apply force, the contact area of the user's hand and the ice making member 100 is larger, the force is easier to be applied, and the pressure to the palm of the user is also small.

Other matters not described in this embodiment can refer to embodiment one.

Embodiment III:

the difference from the first embodiment is that in the present embodiment, in the ice removing state, the ice removing member 300 acts only on the first mold 210 or the second mold 220, and does not deform the first mold 210 and the second mold 220 as a whole. For example, the area of the first mold cavity 211 is smaller than that of the second mold cavity 221, and after the mold is opened, the second mold cavity 221 has larger contact area with ice cubes, so that the ice cubes can be retained in the second mold cavity 221 with a high probability, and therefore, the first mold 210 does not need to be pressed to deform, and only the second mold 220 is pressed to release the ice cubes. Similarly, when the area of the first cavity 211 is larger than that of the second cavity 221, ice cubes will remain in the first cavity 211 with a high probability, and thus, the ice cubes are removed by simply pressing the first mold 210 with the ice removing member 300 to deform the whole.

Other matters not described in this embodiment can refer to embodiment one.

Embodiment four:

the difference between this embodiment and the first embodiment is that only one first supporting member 110 and only one second supporting member 120 are provided, and then both the first supporting member 110 and the second supporting member 120 can be disposed at positions corresponding to the center of the ice making mold 200, the ice making member 100 is provided with a supporting column extending upwards, the top end of the supporting column forms the first supporting member 110 to support the first mold 210, the second mold 220 is provided with a sixth opening to allow the supporting column to pass through, and a supporting portion can be disposed on the supporting column to support the bottom surface of the second mold 220 by using the supporting portion. At this time, the number of the ice removing members 300 is preferably two, so that the two ice removing members 300 simultaneously apply force to the mold, thereby maintaining the balance of the mold.

Other matters not described in this embodiment can refer to embodiment one.

Fifth embodiment:

the embodiment is substantially the same as the first embodiment, in that the number of the ice removing members 300 is one, the first opening 212 is disposed at the center of the first mold 210, the ice removing members 300 pass through the first opening 212 and then abut against the second mold 220, and the second mold 220 is far away from the first mold 210, and in the ice removing state, the center of the second mold 220 is extruded by the ice removing members 300 to generate integral deformation. The abutting portion 310 of the ice removing member 300 abuts against the first mold 210 to integrally deform the first mold 210.

Other matters not described in this embodiment can refer to embodiment one.

Example six:

the difference between this embodiment and the first embodiment is that the ice removing member 300 of this embodiment does not have the abutting portion 310, and after the ice removing member 300 passes through the first mold 210 to act on the second mold 220, the second mold 220 is far away from the first mold 210, and the ice removing member 300 is matched with the second support 120 to integrally deform the second mold 220. In this process, the ice removing member 300 does not act on the first mold 210, and thus the first supporting member 110 only acts on the first mold 210. The technical effect of de-icing of the ice tray mould without contacting can be achieved by the scheme of the embodiment.

Other matters not described in this embodiment can refer to embodiment one.

Example 7:

the present embodiment is substantially the same as the first embodiment, in that the ice removing member 300 of the present embodiment has an abutting portion 310, but the distance between the abutting portion 310 and the end of the ice removing member 300 is smaller than the height difference between the first supporting members 110 and the second supporting member 120. After the ice removing member 300 passes through the first mold 210 to act on the second mold 220, the second mold 220 is separated from the first mold 210, but the ice removing member 300 cannot be engaged with the second support 120 due to insufficient length of the ice removing member 300, so that the second mold 220 is integrally deformed. However, in this process, the abutting portion 310 of the ice removing member 300 abuts against the first mold 210, so that the abutting portion 310 cooperates with the first support member 110 to integrally deform the first mold 210. The technical effect of de-icing of the ice tray mould without contacting can be achieved by the scheme of the embodiment.

Other matters not described in this embodiment can refer to embodiment one. The above embodiments are merely illustrative embodiments of the present utility model, but the technical features of the present utility model are not limited thereto, and any changes or modifications made by those skilled in the art within the scope of the present utility model are included in the scope of the present utility model.

Claims (25)

1. An ice making box comprises an ice making piece (100) and an ice making mould (200) arranged in the ice making piece (100), and is characterized by further comprising an ice removing piece (300), wherein a first supporting piece (110) and a second supporting piece (120) are arranged in the ice making piece (100), the ice making mould (200) comprises a first mould (210) and a second mould (220), and the first mould (210) and the second mould (220) are in a mould closing state, a mould opening state and an ice removing state;

in a mold closing state, the first mold (210) and the second mold (220) are closed to form an ice making cavity (230);

in the mold opening state, the ice removing member (300) acts on the ice making mold (200) to open the ice making cavity (230);

in the ice-removing state, the ice-removing member (300) presses the first mold (210), and the first mold (210) is partially supported by the first support member (110) in the ice-making member (100) to generate integral deformation; or/and, the ice removing member (300) presses the second mold (220), and the second mold (220) is partially supported by the second support member (120) in the ice making member (100) to generate integral deformation.

2. The ice-making housing according to claim 1, wherein in the opened state, said ice-removing member (300) acts on an end face of said second mold (220) facing said first mold (210); in the ice-removing state, the first supporting piece (110) is in contact with the end face of the first die (210) facing the second die (220), and the second supporting piece (120) is in contact with the end face of the second die (220) facing away from the first die (210).

3. The ice-making housing according to claim 1, wherein the ice-removing member (300) is provided with an abutting portion (310);

in the ice-releasing state, the abutting portion (310) presses the first die (210), and the end portion of the ice-releasing member (300) presses the second die (220);

or, in the ice-removing state, the abutting portion (310) presses the second mold (220), and the end portion of the ice-removing member (300) presses the first mold (210).

4. An ice-making housing as claimed in claim 3, wherein the first mould (210) is provided with a first opening (212), and the end of the ice-removing member (300) is arranged to abut against the end face of the second mould (220) through the first opening (212).

5. The ice making housing according to claim 3 or 4, wherein a distance between the abutting portion (310) and the end portion of the ice removing member (300) is equal to or greater than a distance between the first mold (210) and the second mold (220) in the mold-opened state.

6. An ice-making housing according to claim 3, wherein said ice-removing member (300) passes from an edge of said first mold (210) and abuts an end face of said second mold (220).

7. The ice making housing according to any one of claims 1 to 4, wherein said ice making member (100) comprises a housing (130) and an upper cover (140) covering said housing (130), said upper cover (140) being provided with a second opening (150) for said ice removing member (300) to penetrate into said ice making member (100).

8. The ice-making housing as claimed in claim 7, wherein said upper cover (140) has a placement cavity (141) for placing said ice-removing member (300).

9. An ice-making housing according to any one of claims 1-4, wherein the bottom of the ice-making member (100) is provided with a third opening (161) for the passage of an ice-removing member (300) into the ice-making member (100).

10. The ice making housing according to claim 1 or 2, wherein a guide post (170) is provided in the ice making member (100), a fourth opening adapted to the guide post (170) is provided in the second mold (220), and the guide post (170) passes through the fourth opening (222).

11. The ice-making housing according to claim 1, wherein said first support (110) is supported at an edge of said first mold (210); or/and, the second support (120) is supported at the edge of the second mould (220).

12. The ice making housing of claim 11, wherein said ice removing member (300) includes a rod (320) for abutting against either the first mold (210) or the second mold (220), a projection surface of said rod (320) being misaligned with a projection surface of said first support member (110), a projection surface of said rod (320) being misaligned with a projection surface of said second support member (120).

13. The ice-making housing according to claim 1 or 11 or 12, wherein the ice-removing member (300) comprises a first ice-removing member (330) and a second ice-removing member (340);

-the first and second de-icing elements (330, 340) are pressed against the edge of the first mould (210);

alternatively, the first and second de-icing pieces (330, 340) press against the edge of the second mold (220).

14. The ice making housing of claim 13, wherein said first ice removing member (330) and said second ice removing member (340) press against an edge of said first mold (210), two of said first supporting members (110) are provided, and a line connecting projections of said two first supporting members (110) on said first mold (210) intersects a line connecting projections of said first ice removing member (330) and said second ice removing member (340) on said first mold (210).

15. The ice making housing of claim 13, wherein said first ice removing member (330) and said second ice removing member (340) press against an edge of said second mold (220), two of said second supporting members (120), and a line connecting projections of said two second supporting members (120) on said second mold (220) intersects a line connecting projections of said first ice removing member (330) and said second ice removing member (340) on said second mold (220).

16. The ice making housing as claimed in claim 13, wherein the ice making mold (200) has a cross section of a polygonal shape having at least four sides, and the first ice removing member (330) and the second ice removing member (340) are positioned at both ends of one diagonal line of the ice making mold (200).

17. The ice making housing as claimed in claim 16, wherein there are two first supports (110), and two first supports (110) are disposed at both ends of the other diagonal line of the ice making mold (200).

18. The ice making housing as claimed in claim 16, wherein there are two second supports (120), and the two second supports (120) are located at both ends of the other diagonal line of the ice making mold (200).

19. The ice making housing according to any one of claims 1-4, wherein said first mold (210) and said second mold (220) are brought into a closed-mold state by an elastic snap-fit connection or interference fit.

20. An ice-making housing according to any one of claims 1 to 4, wherein a lower deformation space (180) for integrally deforming the second mold (220) is left between the end surface of the second mold (220) and the bottom of the ice-making member (100).

21. The ice making housing according to any one of claims 1 to 4, wherein a distance between an end surface of said first mold (210) facing said second mold (220) and an end surface of said second mold (220) facing said first mold (210) in an open mold state is larger than a height of said ice making cavity (230).

22. The ice making housing as claimed in any one of claims 1 to 4, wherein an ice pouring opening (190) is formed in a side wall of said ice making member (100), said ice pouring opening (190) is communicated with said ice making chamber (230) in an opened state, and ice cubes detached from said ice making chamber (230) are detached from said ice making housing from said ice pouring opening (190).

23. The ice-making housing according to claim 1, wherein an ice storage member (400) is provided below the ice-making member (100), and an ice storage chamber (410) storing the ice-making mold (200) is provided in the ice storage member (400).

24. The ice-making housing according to any one of claims 1 to 4, wherein said first support member (110) and said second support member (120) are each provided on a side wall of said ice-making member (100); -the second support (120) is closer to the centre of the ice making member (100) with respect to the first support (110);

alternatively, the first support (110) is closer to the center of the ice making member (100) than the second support (120).

25. The ice making box according to claim 1, wherein a containing cavity (101) is arranged in the ice making piece (100), the ice making mold (200) is arranged in the containing cavity (101), a plurality of first mold cavities are arranged on the first mold (210), a second mold cavity corresponding to the first mold cavities is arranged on the second mold (220), and in a mold closing state, the first mold (210) and the second mold (220) are closed, and the first mold cavity and the second mold cavity enclose the ice making cavity (230);

the ice removing piece (300) is in a rod shape, the ice removing piece (300) is provided with an abutting part (310), the abutting part (310) is a protruding block protruding out of the outer surface of the ice removing piece (300), and the number of the ice removing pieces (300) is two;

the edge of the first die (210) is provided with first holes (212) corresponding to the number of the ice removing pieces (300), and in the die opening state, the end part of the ice removing piece (300) passes through the first holes (212) to be abutted with the edge of the second die (220);

two guide posts (170) are arranged on the inner side wall of the accommodating cavity (101), and a fourth opening (222) matched with the guide posts (170) is formed in the edge of the second die (220);

the inner side wall of the accommodating cavity (101) is also provided with two second supporting pieces (120), the two second supporting pieces (120) and the two first supporting pieces (110) are arranged along the diagonal line of the same ice making mould (200), and the two ice removing pieces (300) are arranged along the other diagonal line of the ice making mould (200); the first supporting piece (110) and the second supporting piece (120) are arranged at intervals, and a die opening space is reserved in the die opening direction of the ice making die (200);

In an ice-removing state, the end part of the ice-removing piece (300) presses the edge of the second mould (220), and the second support piece (120) is abutted with the end surface of the second mould (220) facing away from the first mould (210); the abutting part (310) of the ice removing piece (300) presses the first die (210) beside the first hole (212), and the end part of the guide column (170) is the first supporting piece (110) and abuts against the end surface of the first die (210) facing the second die (220); a lower deformation space (180) for enabling the second die (220) to generate integral deformation is reserved between the end face of the second die (220) and the bottom of the ice making piece (100);

the side wall of the ice making piece (100) is also provided with an ice pouring opening (190), and the ice pouring opening (190) is communicated with the ice making cavity (230) in the mold opening state.