CN216132139U - Novel multi-grid ice box - Google Patents

Abstract

The utility model discloses a novel multi-lattice ice box which comprises a box body, wherein a silica gel ice mold is placed in the box body, a hollow opening is formed in a bottom plate of the box body, and the hollow opening is aligned with the silica gel ice mold. According to the utility model, the hollow opening is formed in the bottom plate of the box body, and after the ice block is formed in the silica gel ice mold, thrust can be applied to the silica gel ice mold exposed in the hollow opening until the silica gel ice mold is withdrawn from the box body, and then the ice mold is taken out from the silica gel ice mold.

Description

Novel multi-grid ice box

Technical Field

The utility model relates to an ice box, in particular to a novel multi-grid ice box.

Background

An ice bin is a device for forming ice cubes. The existing ice box is generally characterized in that a forming opening is formed in an ice mold, and the ice mold is placed in a refrigerator for freezing after water is injected into the forming opening, so that ice blocks are condensed and formed. The existing ice mold is generally made of hard plastic or silica gel, and for the silica gel ice mold, the silica gel ice mold is generally arranged in a preset box and then put into a refrigerator, and the ice block is expanded in the forming process, so that the silica gel ice mold can be clamped between the ice block and the box, and the ice mold is difficult to take out due to large friction force between the ice mold and the box, so that the ice mold is inconvenient to operate when a user takes ice, and the application requirement cannot be met.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem of providing a novel multi-grid ice box which is simple in structure, easy to take out an ice mold and convenient to use, aiming at the defects of the prior art.

In order to solve the technical problems, the utility model adopts the following technical scheme.

The utility model provides a novel many check ice box, its including the box body, place silica gel ice mold in the box body, the fretwork opening has been seted up on the bottom plate of box body, the fretwork opening with silica gel ice mold aligns.

Preferably, the top of the box body is covered with a box cover, and the box cover covers the upper part of the silica gel ice mold.

Preferably, a plurality of forming notches distributed in an array form are formed in the silica gel ice mold.

Preferably, a transverse slot and a plurality of uniformly distributed longitudinal slots are formed in the bottom of the silica gel ice mold, the plurality of longitudinal slots are perpendicular to the transverse slot, the transverse slot and the longitudinal slots divide the lower end of the silica gel ice mold into a plurality of unit ice molds with the same size, and the forming notches correspond to the unit ice molds one to one.

Preferably, a plurality of hollowed-out openings are formed in the bottom plate of the box body, and the hollowed-out openings correspond to the unit ice molds one to one.

Preferably, a downward protruding boss is formed on the bottom surface of the unit ice mold, and the boss is clamped in the hollow opening.

Preferably, the boss is a circular boss, and the hollowed-out opening is a circular opening.

Preferably, a transverse partition plate and a plurality of longitudinal partition plates which are uniformly distributed are formed in the box body, the longitudinal partition plates are perpendicular to the transverse partition plate, the transverse partition plate is inserted into the transverse slot, and the longitudinal partition plate is inserted into the longitudinal slot.

Preferably, the transverse slot and the longitudinal slot are both "V" shaped in cross-section.

Preferably, the lid and the edge of the box are connected by a hinge.

In the novel multi-grid ice box disclosed by the utility model, the hollow opening is formed in the bottom plate of the box body, and after ice blocks are formed in the silica gel ice mold, thrust can be applied to the silica gel ice mold exposed in the hollow opening until the silica gel ice mold is withdrawn from the box body, and then the ice mold is taken out from the silica gel ice mold.

Drawings

FIG. 1 is a perspective view of a multi-compartment ice bin of the present invention;

FIG. 2 is an internal structural view of the multi-compartment ice bin of the present invention;

FIG. 3 is a first structural diagram of the multi-compartment ice bin of the present invention when the silica gel ice mold is removed;

FIG. 4 is a bottom block diagram of the multi-compartment ice bin of the present invention;

FIG. 5 is a second structural view of the multi-compartment ice bin of the present invention with the silica gel mold removed;

FIG. 6 is a bottom structure view of a silica gel ice mold;

FIG. 7 is a view showing the structure of the case body and the case cover;

FIG. 8 is a first block diagram of an alternative embodiment of the present invention;

FIG. 9 is a block diagram of a second alternative embodiment of the present invention;

fig. 10 is a structural view of another alternative embodiment of the present invention.

Detailed Description

The utility model is described in more detail below with reference to the figures and examples.

The utility model discloses a novel multi-lattice ice box which is shown by combining figures 1 to 7 and comprises a box body 1, wherein a silica gel ice mold 3 is placed in the box body 1, a hollow opening 11 is formed in a bottom plate 10 of the box body 1, and the hollow opening 11 is aligned with the silica gel ice mold 3.

In the structure, the bottom plate 10 of the box body 1 is provided with the hollowed opening 11, after the ice block is formed in the silica gel ice mold 3, thrust can be applied to the silica gel ice mold 3 exposed in the hollowed opening 11 until the silica gel ice mold 3 is withdrawn from the box body 1, and then the ice mold is taken out from the silica gel ice mold 3.

Furthermore, a box cover 2 is covered at the top of the box body 1, and the box cover 2 covers the upper part of the silica gel ice mold 3.

In order to form a plurality of ice blocks simultaneously, in this embodiment, the silica gel mold 3 is provided with a plurality of forming notches 30 distributed in an array manner.

As a preferable mode, a transverse slot 31 and a plurality of longitudinal slots 32 are formed in the bottom of the silica gel ice mold 3, the plurality of longitudinal slots 32 are perpendicular to the transverse slot 31, the transverse slot 31 and the longitudinal slots 32 divide the lower end of the silica gel ice mold 3 into a plurality of unit ice molds 33 with the same size, and the forming notches 30 correspond to the unit ice molds 33 one to one.

In the above structure, by providing the transverse slot 31 and the plurality of longitudinal slots 32, the lower end of the silica gel ice mold 3 can be divided into a plurality of unit ice molds 33 with the same size, and after the silica gel ice mold 3 is taken out, the silica gel ice mold 3 can be pulled up and down, so that ice blocks can be separated from the unit ice molds 33 more easily.

As a preferable mode, a plurality of hollow openings 11 are formed in the bottom plate 10 of the box body 1, and the hollow openings 11 correspond to the unit ice molds 33 one to one. Based on the corresponding relation, the pushing force is applied to the unit ice molds 33, so that the silica gel ice molds 3 can be taken out more conveniently and easily.

In order to ensure the tightness between the silica gel ice mold 3 and the box body 1, in this embodiment, a downwardly protruding boss 34 is formed on the bottom surface of the unit ice mold 33, and the boss 34 is clamped in the hollow opening 11.

Preferably, the boss 34 is a circular boss, and the hollow opening 11 is a circular opening.

In this embodiment, a transverse partition plate 12 and a plurality of longitudinal partition plates 13 are formed in the box body 1, the longitudinal partition plates 13 are all perpendicular to the transverse partition plate 12, the transverse partition plate 12 is inserted into the transverse slot 31, and the longitudinal partition plates 13 are inserted into the longitudinal slot 32.

In order to facilitate the insertion or extraction of the silica gel mold 3, in the present embodiment, the transverse slot 31 and the longitudinal slot 32 are both V-shaped in cross section.

In this embodiment, the box cover 2 preferably adopts a flip structure, specifically, the edges of the box cover 2 and the box body 1 are connected through a hinge 20.

In practical application, the silica gel molds 3 may be arranged in an 8-grid structure, that is, 4 grids in the transverse direction are multiplied by 2 grids in the longitudinal direction, but the specific number of grids is not limited in the present invention, and as shown in fig. 8 and 9, in an alternative mode of the present invention, the silica gel molds 3 may also be arranged in a 6-grid structure, and of course, may also be arranged in a 4-grid structure as shown in fig. 10.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents or improvements made within the technical scope of the present invention should be included in the scope of the present invention.

Claims (9)

1. The utility model provides a novel many check ice box, a serial communication port, including the box body, the silica gel ice mould has been placed in the box body, set up a plurality of shaping notches that are array distribution on the silica gel ice mould, the fretwork opening has been seted up on the bottom plate of box body, the fretwork opening with the silica gel ice mould aligns.

2. The novel multi-grid ice box as claimed in claim 1, wherein a box cover is covered on the top of the box body, and the box cover covers the silica gel ice mold.

3. The novel multi-grid ice box as claimed in claim 1, wherein a transverse slot and a plurality of uniformly distributed longitudinal slots are formed in the bottom of the silica gel ice mold, the plurality of longitudinal slots are perpendicular to the transverse slot, the transverse slot and the longitudinal slots divide the lower end of the silica gel ice mold into a plurality of unit ice molds with the same size, and the forming notches correspond to the unit ice molds one to one.

4. The novel multi-grid ice box as claimed in claim 3, wherein a plurality of hollowed-out openings are formed on the bottom plate of the box body, and the hollowed-out openings correspond to the unit ice molds one to one.

5. The novel multi-grid ice box as claimed in claim 4, wherein a downward protruding boss is formed on the bottom surface of the unit ice mold, and the boss is clamped in the hollow opening.

6. The novel multi-tray ice bin of claim 5, wherein the bosses are circular bosses and the hollowed-out openings are circular openings.

7. The novel multi-compartment ice bin as claimed in claim 3, wherein a transverse partition and a plurality of evenly distributed longitudinal partitions are formed in the bin body, the longitudinal partitions are perpendicular to the transverse partition, the transverse partition is inserted into the transverse slot, and the longitudinal partitions are inserted into the longitudinal slot.

8. The new multi-compartment ice bin of claim 7 wherein said transverse slots and said longitudinal slots are each "V" shaped in cross section.

9. A novel multi-compartment ice bin as claimed in claim 2 wherein the lid and the edge of the bin body are connected by a hinge.

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