CN104422219A - Ice maker - Google Patents

Abstract

The invention provides an ice maker. The ice maker includes: a freezing plate configured to be cooled by an evaporator to freeze water flowing thereon; a water tub disposed below the freezing plate to collect water falling from the freezing plate; an ice bin forming an ice storage space around the water tub to collect ice falling from the freezing plate; and a plate-shaped ice storage guide placed on an upper end of the water tub between the freezing plate and the water tub, the ice storage guide including a sloped part inclined toward the ice bin and a plurality of discharge holes narrower than widths of ice cubes formed by the freezing plate. Parts of the ice maker are simple and can be easily cleaned, and thus the ice maker may be hygienically used.

Description

Ice machine

The cross reference of related application

This application claims the priority of the Korean Patent Application No. 10-2013-0106017 submitted on September 4th, 2013 to Korean Intellectual Property Office, its full content is incorporated to herein by reference.

Background technology

The present invention relates to a kind of ice machine, relate more specifically to a kind of ice machine comprising ice storage guider, this ice storage guider is used for the water fallen from freezing plate and ice to separate to prevent water from flowing in refrigerator-freezer.

In a kind of down flow type ice machine, when water flows down along the freezing plate by evaporator cools, water freezes, for ice, to be stored in refrigerator-freezer after ice and freezing plate separate.

With reference to Fig. 1, down flow type ice machine of the prior art comprises: ice making unit, and it comprises evaporimeter 10, freezing plate 12 and feed pipe 14; Bucket 20, it is arranged under ice making unit to collect the ice making water fallen from freezing plate 12 and the water separated with ice; And ice guider 30, it is arranged on the upper end of bucket 20 ice and water to be separated, and the refrigerator-freezer (not shown) be arranged on outside bucket 20 that ice is led.

With reference to Fig. 2 and Fig. 3, ice guider 30 of the prior art comprises: multiple with the vertical baffle 32 of regular intervals setting and the connecting portion 34 connecting described vertical baffle 32.

The upper end of vertical baffle 32 has inclined-plane ice to be led refrigerator-freezer.

When ice machine operates, the parts that ice guider 30 contacts with water with bucket 20 grade may be covered with incrustation scale (dirt).Therefore, can carry out cleaning to remove the incrustation scale formed on these parts, thus wholesomely use ice machine.

But the interval be set up due to the vertical baffle 32 of ice guider 30 in prior art is less than the size of ice cube, so the structure of ice guider 30 is very complicated, be thus difficult to clean ice guider 30.

In addition, as shown in Figure 3, the upper end of ice guider 30 hangs over the upper end of bucket 20.Therefore, the water flowed down from freezing plate 12 can flow into refrigerator-freezer along the inclined-plane of vertical baffle 32 upper end, thus makes the ice-out that is stored in refrigerator-freezer.

Infiltrate in refrigerator-freezer like that if water is as described above, the ice be so stored in refrigerator-freezer may melt, and thus the quality of ice just may decline.

Summary of the invention

One aspect of the present invention can provide a kind of ice machine, and described ice machine is configured to be easy to cleaning, and for storing ice after ice is separated completely with water.

According to an aspect of the present invention, a kind of ice machine can comprise: freezing plate, its by evaporator cools to make the water flow through from described freezing plate freeze; Bucket, it is arranged under described freezing plate to collect the water flowed down from described freezing plate; Refrigerator-freezer, it forms ice storage area to collect the ice fallen from described freezing plate around described bucket; And tabular ice storage guider, it is placed in the upper end of described bucket, and between described freezing plate and described bucket, described ice storage guider comprises the rake that tilts towards described refrigerator-freezer and multiple tap, and the width of the ice cube that the width of described multiple tap is formed than described freezing plate is less.

Described tap can extend on the incline direction of described rake.

Described ice storage guider can comprise further from the outstanding and ribs extended along its length direction vertical on rear side of it.

End plate can be set at the two ends of described ice storage guider, to support the main body of described ice storage guider relative to the upper end of described bucket.

Described ice storage guider comprises auxiliary discharge hole further, and described auxiliary discharge hole to be formed in before described tap and to separate with described tap.

Described auxiliary discharge hole can be formed between described tap adjacent one another are.

Multiple auxiliary discharge hole can be arranged on the length direction of described ice storage guider by predetermined space; And guiding jaw (guide jaw) can be formed with between adjacent described auxiliary discharge hole, the water flowed on described rake to be led described auxiliary discharge hole.

When described ice storage guider is placed on described bucket, can be formed to discharge between one end of described ice storage guider and the upper end of the inwall of described bucket and stitch.

Described ice storage guider can comprise the direction protrusion (guide protrusion) be formed on described rake one end further.

The ridge (ridges) that the edge that described ice storage guider can be included in described tap further gives prominence to from described rake.

Described freezing plate comprises front freezing plate and rear freezing plate, described front freezing plate and described rear freezing plate respectively with two end in contact of described evaporimeter, and the front and rear of described ice storage guider is symmetrical, to lead to the ice fallen from described front freezing plate and described rear freezing plate respectively.

Accompanying drawing explanation

Above-mentioned and other aspect, feature and advantage of the present invention is more clearly understood from the detailed description done below in conjunction with accompanying drawing, in the accompanying drawings:

Fig. 1 is the perspective view representing the assembly be included in the ice machine of prior art, and this assembly comprises ice making unit, bucket and ice guider;

Fig. 2 is the perspective view representing ice guider in Fig. 1;

Fig. 3 is the enlarged drawing representing part A in Fig. 1;

Fig. 4 represents the side cross-sectional views be included according to the assembly in the ice machine of the embodiment of the present invention, and this assembly comprises freezing plate, evaporimeter, ice storage guider, bucket and refrigerator-freezer;

Fig. 5 is the perspective view of the ice storage guider representing ice machine shown in Fig. 4;

Fig. 6 is the close up perspective view of the ice storage guider represented in Fig. 5;

Fig. 7 is the perspective view of the part representing assembly shown in Fig. 4;

Fig. 8 represents that the guider of ice storage shown in Fig. 5 is placed in the sectional view of the state on bucket; And

Fig. 9 is the partial enlarged drawing representing the guider of ice storage shown in Fig. 8.

Detailed description of the invention

Below with reference to accompanying drawings exemplary embodiment of the present invention is described in detail.

But the present invention also other different forms many can carry out example, and the present invention should not be construed as the specific embodiment being limited to and listing herein.On the contrary, these embodiments are provided to be to make the present invention more detailed and complete, and in order to fully pass on scope of the present invention to those skilled in the art.

In the accompanying drawings, for clarity sake, the shape of element and size may be exaggerated to some extent, and drawing reference numeral identical in all of the figs represents same or analogous element.

In the following description, technical term only for explaining specific exemplary embodiment, is not construed as limiting scope and spirit of the present invention.Unless indication is contrary, otherwise the term of singulative also can comprise plural form.

Hereinafter, with reference to the accompanying drawings exemplary embodiment of the present invention is described.

With reference to Fig. 4 to Fig. 9, will be described ice machine 200 according to embodiments of the invention.

Fig. 4 represents the side cross-sectional views be contained according to the assembly in the ice machine 200 of the embodiment of the present invention, and this assembly comprises freezing plate 210, evaporimeter 220, ice storage guider 100, bucket 230 and refrigerator-freezer 24.Fig. 5 and Fig. 6 is the perspective view and the partial enlarged drawing that represent ice storage guider 100 respectively.Fig. 7 is the perspective view of the part representing assembly shown in Fig. 4.Fig. 8 and Fig. 9 represents that ice storage guider 100 is placed in sectional view and the partial enlarged drawing of the state on bucket 230.

With reference to Fig. 4 to Fig. 9, according to embodiments of the invention, ice machine 200 comprises freezing plate 210, evaporimeter 220, bucket 230, refrigerator-freezer 240 and ice storage guider 100.

Freezing plate 210 can be undertaken cooling (hereinafter describing) by evaporimeter 220, and water can freeze when flowing down along the surface of freezing plate 210.

In an embodiment, freezing plate 210 can comprise front freezing plate 210a and rear freezing plate 210b, front freezing plate 210a and rear freezing plate 210b respectively with front side and the rear contact of evaporimeter 220.But the configuration of freezing plate 210 is not limited thereto.

Evaporimeter 220 can comprise pipeline, and cold-producing medium flows in this pipeline.This pipeline can be the zigzag with multiple sweep.

As shown in Figure 4, evaporimeter 220 can with the rear contact of freezing plate 210 to cool freezing plate 210.

Bucket 230 can be arranged under freezing plate 210 to collect the water (ice making water and the water separated with ice) flowed down from freezing plate 210.

Refrigerator-freezer 240 can form ice storage area around bucket 230, to collect the ice fallen from freezing plate 210.

Ice storage guider 100 is placed in the upper end of bucket 230, between freezing plate 210 and bucket 230.

Ice storage guider 100 can by the ice that falls from freezing plate 210 and water separately, and lead ice refrigerator-freezer 240 bucket 230 that led by water.

Hereinafter, with reference to Fig. 5 to Fig. 9, ice storage guider 100 is further described in more detail.

In an embodiment, ice storage guider 100 can comprise rake 110 and tap 120.Rake 110 can comprise ridge 125, ribs 130, end plate 140, auxiliary discharge hole 150, guiding jaw 160 and direction protrusion 170.

Ice storage guider 100 is formed as tabular component, and rake 110 is downward-sloping.

Under the state that ice storage guider 100 is placed on bucket 230, the inclined-plane of rake 110 is downward-sloping towards refrigerator-freezer 240.

Tap 120 is located in the permeability hole on ice storage guider 100.The width of the ice cube of width comparable freezing plate 210 formation of tap 120 is less.

Tap 120 can be arranged along whole ice storage guider 100.

In an embodiment, tap 120 can extend on the incline direction of rake 110.

Extend on the incline direction of rake 110 like that if tap 120 is as described above, ice can be easy to slide on rake 110, and can not be discharged hole 120 and block.

In addition, in an embodiment, ridge 125 can be formed along the edge of tap 120.

In other words, ridge 125 can be the edge of tap 120, and ridge 125 projects upwards from rake 110.

When ice slides on rake 110, due to ridge 125, the contact surface between ice and rake 110 can reduce.In other words, due to ridge 125, ice can linearly contact with rake 110 but not carry out face with rake 110 and contact.

Ridge 125 can be stuck in and have on the rake 110 of even shape by anti-stagnant ice, thus ice is slided swimmingly on rake 110.

The upper end of ridge 125 can be circle, farthest to reduce the contact surface between rake 110 and ice.

Ribs 130 vertically can be given prominence to from the rear surface of rake 110, and can extend along the length direction of rake 110.

Due to ribs 130, the resistance of ice storage guider 100 pairs of normal loads of tabular is improved.That is, ribs 130 strengthens ice storage guider 100, prevents ice storage guider 100 from being fallen thereon ice compressive strain or damage.

End plate 140 can be arranged on the two ends of ice storage guider 100 to support the main body of ice storage guider 100 relative to bucket 230.

In an embodiment, end plate 140 can be the two ends that are arranged on ice storage guider 100 and from here to the tabular component of downward-extension.

By being arranged on the lower end of end plate 140 on the upper end of bucket 230, ice storage guider 100 can be fixed to the upper end of bucket 230.

In an embodiment, end plate 140 can be plate-like shape, and end plate 140 can single formation or be integrally coupled to the two ends of ice storage guider 100 to reinforce ice storage guider 100, thus prevent ice storage guider 100 from bending due to weight.

As shown in Figure 5 and Figure 6, auxiliary discharge hole 150 can be formed in before tap 120 (based on the flow direction of ice and water, being positioned at the downstream direction of tap 120) and can separate with tap 120.

Similar to tap 120, auxiliary discharge hole 150 is permeability hole, to discharge the water of flowing on rake 110 on the rake 110 that this permeability hole is formed in ice storage guider 100.The width of the ice cube of width comparable freezing plate 210 formation of auxiliary discharge hole 150 is less.

In an embodiment, auxiliary discharge hole 150 can be in line be arranged on ice storage guider 100 length direction on.

And in an embodiment, auxiliary discharge hole 150 can be formed between adjacent tap 120.In other words, tap 120 and the auxiliary discharge hole 150 be arranged on ice storage guider 100 length direction can be interlaced.

In this case, between tap 120, the water of flowing is discharged by auxiliary discharge hole 150.

And in an embodiment, auxiliary discharge hole 150 can be separated from each other, guiding jaw 160 can be formed between auxiliary discharge hole 150.

Guiding jaw 160 can be outstanding so that the water guiding auxiliary discharge hole 150 will flowed at rake 110 from rake 110.

In an embodiment, as shown in Figure 7 to 9, when ice storage guider 100 is placed on bucket 230, can be formed to discharge between the upper end of the inwall of the edge of ice storage guider 100 and bucket 230 and stitch.

In other words, the width of ice storage guider 100 vertical width comparable bucket 230 is less, thus can form horizontal joint (discharge and stitch) between ice storage guider 100 and the inwall of bucket 230.

Arrive the front end of ice storage guider 100 but not by the water that tap 120 and auxiliary discharge hole 150 are discharged, be finally expelled to bucket 230 by discharging seam.

Direction protrusion 170 can be outstanding towards discharge seam from the front end of ice storage guider 100.

On the length direction being disposed on ice storage guider 100 that direction protrusion 170 can be less than ice cube width.

Direction protrusion 170 can prevent ice cube from falling from discharge seam.

Above-mentioned ice storage guider 100 is substantially flat shape, thus can be easy to cleaning.

Because the water of flowing on the rake 110 of ice storage guider 100 is discharged by tap 120, auxiliary discharge hole 150 and discharge seam, so water and ice can separate completely, thus can infiltrate in refrigerator-freezer 240 by anti-sealing.

And in an embodiment, the front and rear of ice storage guider 100 can be symmetrical, thus the ice that the past freezing plate 210a and rear freezing plate 210b falls is led.

As above, according to exemplary embodiment of the present invention, the modular construction due to ice machine is simple and can be easy to cleaning, thus ice machine can wholesomely use.

In addition, according to embodiments of the invention, the ice fallen from freezing plate and water can be separated from each other, thus prevent water from flowing in refrigerator-freezer, thus can reliably make high-quality ice.

Although illustrated exemplary embodiment above and described, those skilled in the art should be clear, under the condition not deviating from the spirit and scope of the present invention limited in appended claims, can make various modifications and variations.

Claims (11)

1. an ice machine, comprising:

Freezing plate, is set to by evaporator cools to make the water flow through from described freezing plate freeze;

Bucket, is arranged under described freezing plate to collect the water flowed down from described freezing plate;

Refrigerator-freezer, forms ice storage area to collect the ice fallen from described freezing plate around described bucket; And

Tabular ice storage guider, be placed in described bucket upper end and between described freezing plate and described bucket, described ice storage guider comprises the rake that tilts towards described refrigerator-freezer and multiple tap, and the width of described multiple tap is narrower than the width of the ice cube formed by described freezing plate.

2. ice machine as claimed in claim 1, wherein, described tap extends on the incline direction of described rake.

3. ice machine as claimed in claim 1, wherein, described ice storage guider comprises further from the outstanding and ribs extended along its length direction vertical on rear side of it.

4. ice machine as claimed in claim 1, wherein, is provided with end plate at the two ends of described ice storage guider, to support the main body of described ice storage guider relative to the upper end of described bucket.

5. ice machine as claimed in claim 1, wherein, described ice storage guider comprises auxiliary discharge hole further, and described auxiliary discharge hole to be formed in before described tap and to separate with described tap.

6. ice machine as claimed in claim 5, wherein, described auxiliary discharge hole is formed between described tap adjacent one another are.

7. ice machine as claimed in claim 6, wherein, the length direction along described ice storage guider is provided at predetermined intervals multiple auxiliary discharge hole; And

Guiding jaw is formed with, the water flowed on described rake to be led described auxiliary discharge hole between adjacent described auxiliary discharge hole.

8. ice machine as claimed in claim 1, wherein, when described ice storage guider is placed on described bucket, is formed to discharge and stitches between one end of described ice storage guider and the upper end of the inwall of described bucket.

9. ice machine as claimed in claim 8, wherein, described ice storage guider comprises the direction protrusion be formed on described rake one end further.

10. ice machine as claimed in claim 1, wherein, the ridge that the edge that described ice storage guider is included in described tap further gives prominence to from described rake.

11. ice machines as claimed in claim 1, wherein, described freezing plate comprises front freezing plate and rear freezing plate, described front freezing plate and described rear freezing plate respectively with two end in contact of described evaporimeter, and

The front and rear of described ice storage guider is symmetrical, to lead to the ice fallen from described front freezing plate and described rear freezing plate respectively.