CN119309365A - Ice moving device and refrigeration equipment - Google Patents

Abstract

The present application provides an ice moving device and a refrigeration equipment, the ice moving device is used for the refrigeration equipment, the ice moving device includes: an ice moving part, having an ice moving cavity, the ice moving part including a first side panel and a second side panel arranged opposite to each other; an ice moving piece, rotatably arranged in the ice moving cavity; a first panel and a second panel, the first panel is a part of the first side panel, the second panel is a part of the second side panel, the first panel is arranged on one side of the ice moving piece, the second panel is arranged on the other side of the ice moving piece, the first panel and the second panel rotate with the ice moving piece, the ice moving piece will not rub the first panel and/or the second panel, thereby achieving the goal of avoiding the ice moving piece from rubbing against the first side panel and/or the second side panel without increasing the distance between the ice moving piece and the first side panel and between the ice moving piece and the second side panel.

Description

Ice moving device and refrigeration equipment

Technical Field

The application relates to the technical field of ice making, in particular to an ice moving device and refrigeration equipment.

Background

In the existing refrigeration equipment with an integrated refrigeration and ice making function, ice cubes made by an ice making machine are transported to an ice taking assembly through an ice moving device, an ice moving component used for driving the ice cubes to move is arranged in the ice moving device, in order to avoid friction of a shell in the process of moving the ice moving component, a sufficient distance needs to be kept between the ice moving component and the shell, and therefore the ice moving device is too large in size and occupies too much space of the refrigeration equipment, and therefore, how to provide the ice moving device so as to reduce the size of the ice moving device while avoiding friction of the ice moving component on the shell is a technical problem to be solved in the field.

Disclosure of Invention

In view of the above problems, the present application provides an ice moving device and a refrigeration apparatus, so as to solve the technical problem that the friction between the ice moving component and the housing is avoided and the volume of the ice moving device is reduced.

In order to solve the technical problems, the technical scheme adopted by the application is as follows:

The application provides an ice moving device which is arranged on refrigeration equipment and comprises an ice moving part, an ice moving piece, a first panel and a second panel, wherein the ice moving part is provided with an ice moving cavity, the ice moving part is arranged in the ice moving cavity in a rotatable mode, the first panel is a part of the first side plate, the second panel is a part of the second side plate, the first panel is arranged on one side of the ice moving piece, the second panel is arranged on the other side of the ice moving piece, and the first panel and the second panel rotate along with the ice moving piece.

The ice moving part is further provided with an ice moving inlet and an ice moving outlet which are communicated with the ice moving cavity, and the ice moving piece is used for rotating along a first direction so as to drive ice cubes entering the ice moving cavity from the ice moving inlet to be thrown out towards the ice moving outlet.

The ice moving part comprises a rotating shaft and an ice moving body, the rotating shaft comprises a rotating shaft main body, a first extending part and a second extending part, the rotating shaft main body is located between the first extending part and the second extending part, and the ice moving body is arranged on the rotating shaft main body.

The ice moving part further comprises a shaft sleeve, the shaft sleeve is sleeved on the rotating shaft main body, the first extending part and the second extending part are exposed out of the shaft sleeve, and the ice moving body is arranged on the shaft sleeve or the shaft sleeve and the rotating shaft main body.

Wherein the first extension part is arranged on the first panel in a penetrating way, the second extension part is arranged on the second panel in a penetrating way, the ice moving body is positioned between the first panel and the second panel.

The ice moving piece further comprises a first rotating shaft seat and a second rotating shaft seat, the first rotating shaft seat is arranged on the first extension portion, the first rotating shaft seat is located on one side, facing away from the ice moving cavity, of the first panel, the second rotating shaft seat is arranged on the second extension portion, and the second rotating shaft seat is located on one side, facing away from the ice moving cavity, of the second panel.

The ice moving device further comprises a supporting plate, the supporting plate is located on one side, opposite to the second panel, of the second rotating shaft seat, the rotating shaft is rotatably arranged on the supporting plate, and the rotating shaft is used for driving the ice moving body, the first panel and the second panel to rotate.

Wherein the ice moving body is selected from bristles or fan blades.

The ice moving part further comprises a top cover connected between the first side plate and the second side plate, and a bottom shell with three layers surrounding the first side plate and the second side plate, wherein the first side plate, the second side plate, the top cover and the bottom shell are enclosed to form the ice moving cavity.

The ice moving device further comprises an ice filtering area, the ice filtering area is located at the bottom of the ice moving part, the ice filtering area extends along the direction from the ice moving inlet to the ice moving outlet, and the ice filtering area is used for filtering crushed ice and/or water in the ice moving cavity.

The ice moving part further comprises a pressing plate, the pressing plate is arranged on the top cover and located in the ice moving cavity, and the shortest distance between the end of the pressing plate, which faces the ice moving part, and the central axis of the ice moving part is smaller than the radius of the ice moving part.

In a second aspect, the present application provides a refrigeration appliance comprising an ice displacement device as described above.

Compared with the prior art, the ice moving device and the refrigeration equipment have the beneficial effects that the ice moving device is used for the refrigeration equipment and comprises the ice moving part, the ice moving piece, the first panel and the second panel, the ice moving part is provided with the ice moving cavity, the ice moving part comprises the first side plate and the second side plate which are oppositely arranged, the ice moving piece is rotatably arranged in the ice moving cavity, the first panel is a part of the first side plate, the second panel is a part of the second side plate, the first panel is arranged on one side of the ice moving piece, the second panel is arranged on the other side of the ice moving piece, the first panel and the second panel rotate along with the ice moving piece, and the ice moving piece cannot rub against the first panel and/or the second panel, so that the ice moving piece is prevented from rubbing against the first side plate and/or the second side plate on the premise that the distance between the ice moving piece and the first side plate and the second side plate is not required to be enlarged.

Drawings

For a clearer description of the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly introduced below, it being obvious that the drawings in the description below are only some embodiments of the present application, and that other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art, wherein:

Fig. 1 is a schematic perspective view of an embodiment of an ice removing device according to the present application;

fig. 2 is a schematic perspective view of an ice removing device provided by the application after a supporting plate is hidden;

Fig. 3 is a schematic perspective view of the ice removing device provided by the application after hiding the first side plate;

FIG. 4 is a schematic view of a part of the structure of an ice moving member of the ice moving device provided by the application;

FIG. 5 is a schematic view of an embodiment of an ice moving member of the ice moving device according to the present application;

FIG. 6 is a schematic view of a part of the structure of the ice removing device provided by the application;

fig. 7 is a schematic perspective view of another embodiment of an ice removing device according to the present application;

fig. 8 is a schematic perspective view of another embodiment of an ice removing device according to the present application;

Fig. 9 is a schematic structural view of another embodiment of an ice removing device according to the present application;

Fig. 10 is a schematic perspective view of a refrigeration apparatus according to the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application. It is to be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the application. It should be further noted that, for convenience of description, only some, but not all of the structures related to the present application are shown in the drawings. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

In the description of the present application, it is to be understood that the terms "center", "longitudinal", "transverse", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise"

The orientation or positional relationship indicated by the needle "," counterclockwise ", etc. is based on the orientation or positional relationship shown in the drawings and is merely for convenience of description and to simplify the description, and does not indicate or imply that the device or element in question must have a specific orientation, be constructed and operate in a specific orientation, and therefore should not be construed as limiting the application. 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 one or more of the described features. In the description of the present application, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In the description of the present application, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, mechanically connected, electrically connected, or communicable with each other, directly connected, indirectly connected via an intermediary, or in communication between two elements or in an interaction relationship between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art according to the specific circumstances.

In the present application, unless expressly stated or limited otherwise, a first feature "above" or "below" a second feature may include both the first and second features being in direct contact, as well as the first and second features not being in direct contact but being in contact with each other through additional features therebetween. Moreover, a first feature being "above," "over" and "on" a second feature includes the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly under and obliquely below the second feature, or simply means that the first feature is less level than the second feature.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment may be included in at least one embodiment of the application. The appearances of such phrases in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. Those of skill in the art will explicitly and implicitly appreciate that the embodiments described herein may be combined with other embodiments.

The present application provides an ice removal device 100. Referring to fig. 1 to 3, fig. 1 is a schematic perspective view of an embodiment of an ice moving device according to the present application, fig. 2 is a schematic perspective view of an ice moving device with a hidden support plate according to the present application, and fig. 3 is a schematic perspective view of an ice moving device with a hidden first side plate according to the present application. The ice moving device 100 is used for the refrigerating apparatus 10. The ice moving device includes an ice moving part 110, an ice moving member 120, a first panel 1141, and a second panel 1151. The ice moving part 110 has an ice moving chamber 111. The ice moving part 110 includes a first side plate 114 and a second side plate 115 disposed opposite to each other. The ice moving member 120 is rotatably disposed in the ice moving chamber 111. The first panel 1141 is part of the first side panel 114. The second panel 1151 is part of the second side panel 115. The first panel 1141 is disposed on one side of the ice moving member 120, and the second panel 1151 is disposed on the other side of the ice moving member 120. The first panel 1141 and the second panel 1151 rotate with the ice moving member 120.

The plane of the first side plate 114 and the plane of the second side plate 115 are perpendicular to the central axis of the ice moving member 120. The first side plate 114 and the second side plate 115 may be used as a part of a housing of the ice moving device 100, where the housing of the ice moving device 100 is used as a basic carrier of the ice moving device 100, and may perform a bearing and protecting function on components such as the ice moving member 120 of the ice moving device 100.

In some embodiments, referring to fig. 1-2, the first side panel 114 includes a first panel 1141 and a first side panel body 1142. The first panel body 1142 is disposed around the first panel 1141, and the first panel 1141 is spaced from the first panel body 1142, that is, a certain distance is formed between an edge of the first panel 1141 adjacent to the first panel body 1142 and an edge of the first panel body 1142 adjacent to the first panel 1141, so that the first panel 1141 does not interfere with the first panel body 1142 during the rotation of the first panel 1141 along with the ice moving member 120. The second side panel 115 includes a second panel 1151 and a second side panel body 1152. The second side plate body 1152 is disposed around the second panel 1151, and the second panel 1151 is spaced from the second side plate body 1152, that is, a distance is provided between an edge of the second panel 1151 adjacent to the second side plate body 1152 and an edge of the second side plate body 1152 adjacent to the second panel 1151, so that the second panel 1151 does not interfere with the second side plate body 1152 during rotation of the second panel 1151 along with the ice moving member 120. In some embodiments, the first panel 1141 and the second panel 1151 may have a circular shape, and the centers of the circles of the first panel 1141 and the second panel 1151 are located on the central axis of the ice moving member 120.

It should be noted that, during the movement of the ice removing member 120, if any area of the first side plate 114 and the second side plate 115 remains stationary, the ice removing member 120 is prone to friction with the area of the first side plate 114 where the first panel 1141 is located and the area of the second side plate 115 where the second panel 1151 is located, resulting in damage to the ice removing member 120, the first side plate 114 and/or the second side plate 115. Thus, by providing the first and second panels 1141 and 1151 such that the first and second panels 1141 and 1151 rotate with the ice moving member 120, the ice moving member 120 does not rub against the first and/or second panels 1141 and 1151, thereby avoiding the ice moving member 120 from rubbing against the first and/or second side plates 114 and 115 without expanding the distance between the ice moving member 120 and the first and second side plates 114 and 115.

After the ice cubes enter the ice moving cavity 111, the ice cubes contact with the ice moving member 120 to deform the ice moving member 120, and the ice moving member 120 contacts with the first panel 1141 and/or the second panel 1151, so that the ice moving member 120 does not rub against the first panel 1141 and/or the second panel 1151, and not only is the ice moving member 120, the first panel 1141 and/or the second panel 1151 abraded, but also friction noise is reduced.

In some embodiments, the ice moving part 110 further has an ice moving inlet 112 and an ice moving outlet 113 communicating with the ice moving cavity 111. The ice moving member 120 is configured to rotate in a first direction X for driving ice cubes entering the ice moving chamber 111 through the ice moving inlet 112 to be ejected toward the ice moving outlet 113.

The ice moving member 120 is an ice transporting member. The ice moving member 120 is rotatably disposed in the ice moving chamber 111. The ice moving inlet 112 and the ice moving outlet 113 are located at the outer circumference of the ice moving member 120. The ice moving member 120 is configured to rotate in a first direction X for driving ice cubes entering the ice moving chamber 111 through the ice moving inlet 112 to be ejected toward the ice moving outlet 113. For example, the ice moving member 120 is configured to rotate in a first direction X with ice cubes entering the ice moving chamber 111 through the ice moving inlet 112, and to throw the ice cubes toward the ice moving outlet 113, so that the ice cubes obtain a certain initial velocity, and move from the ice moving outlet 113 to the ice taking assembly 200 (see fig. 10). Because the ice moving member 120 can rotate continuously at a certain speed, ice cubes entering the ice moving cavity 111 from the ice moving inlet 112 can be continuously and rapidly thrown to the ice taking assembly 200, the ice cubes are fast to move, the ice taking efficiency is high, quick and continuous ice taking is realized, the ice taking waiting time of a user is short, the ice cubes are not easy to melt, the ice cube quality is high, and the situation of melting adhesion is not easy to occur between the ice cubes.

In some embodiments, please refer to fig. 4 to 5, fig. 4 is a schematic view of a portion of an ice moving member of the ice moving device according to the present application, and fig. 5 is a schematic view of an embodiment of an ice moving member of the ice moving device according to the present application. The ice moving member 120 includes a rotation shaft 121 and an ice moving body 123. The rotation shaft 121 includes a rotation shaft main body 1211, a first extension 1212, and a second extension 1213. The shaft body 1211 is located between the first extension 1212 and the second extension 1213. The ice moving body 123 is provided to the rotation shaft body 1211.

The main body 1211, the first extension 1212 and the second extension 1213 are fixedly coupled or integrally formed, wherein the first extension 1212 is positioned at an end of one end of the main body 1211 and the second extension 1213 is positioned at an end of the other end of the main body 1211. The rotation shaft body 1211 is positioned in the ice moving cavity 111, the first extension 1212 extends from one end of the rotation shaft body 1211 toward the outside of the ice moving cavity 111, and the second extension 1213 extends from the other end of the rotation shaft body 1211 toward the outside of the ice moving cavity 111.

The ice moving body 123 is provided to the rotation shaft body 1211. The ice moving body 123 may be radially unfolded from the rotation shaft body 1211 toward the outer circumference of the rotation shaft 121. The ice moving body 123 may rotate with the rotation of the rotation shaft body 1211. The ice moving body 123 can rotate in the first direction X, carrying ice cubes entering the ice moving chamber 111 from the ice moving inlet 112, and throw the ice cubes toward the ice moving outlet 113.

In some embodiments, the ice displacement member 120 further includes a bushing 122. The sleeve 122 is sleeved on the main body 1211. First extension 1212 and second extension 1213 are exposed to sleeve 122. The ice moving body 123 is provided to the shaft sleeve 122 or to the shaft sleeve 122 and the rotation shaft body 1211.

The shaft sleeve 122 is sleeved on the rotating shaft main body 1211, and the shaft sleeve 122 is fixed on the rotating shaft main body 1211, and the shaft sleeve 122 can rotate along with the rotation of the rotating shaft main body 1211. The ice moving body 123 may be disposed at the shaft sleeve 122, the ice moving body 123 may be radially unfolded from the shaft sleeve 122 toward the outer circumference of the shaft sleeve 122, or the ice moving body 123 may be disposed at the shaft sleeve 122 and the rotation shaft main body 1211, the ice moving body 123 may be radially unfolded from the shaft sleeve 122 and the rotation shaft main body 1211 toward the outer circumference of the shaft sleeve 122, and the ice moving body 123 and the shaft sleeve 122 may be rotatable with the rotation of the rotation shaft main body 1211.

In some embodiments, the first extension 1212 extends through the first panel 1141. The second extension 1213 extends through the second panel 1151. The ice moving body 123 is located between the first panel 1141 and the second panel 1151.

The first extension 1212 and the second extension 1213 are exposed to the sleeve 122, such that the first extension 1212 extends through the first panel 1141 and the second extension 1213 extends through the second panel 1151. The first panel 1141 may be fixed to the first extension 1212, and the second panel 1151 may be fixed to the second extension 1213, such that the rotation shaft 121 may rotate the first panel 1141 and the second panel 1151.

By disposing the first panel 1141 on the first extension portion 1212 and disposing the second panel 1151 on the second extension portion 1213, and disposing the ice moving body 123 on the shaft sleeve 122 and/or the shaft main body 1211, the shaft 121 can drive the first panel 1141, the second panel 1151 and the ice moving body 123 to rotate, so that the first panel 1141 and the second panel 1151 rotate along with the rotation of the ice moving member 120, and therefore, the friction of the ice moving member 120 on the first side plate 114 and/or the second side plate 115 can be avoided without enlarging the distance between the ice moving member 120 and the first side plate 114 and the distance between the ice moving member 120 and the second side plate 115.

In some embodiments, the ice moving member 120 further includes a first rotational shaft seat 124 and a second rotational shaft seat 125. The first rotating shaft seat 124 is disposed on the first extension 1212. The first pivot seat 124 is located at a side of the first panel 1141 facing away from the ice moving cavity 111. The second pivot seat 125 is disposed on the second extension 1213. The second pivot seat 125 is located on a side of the second panel 1151 facing away from the ice moving cavity 111.

The rotating shaft 121, the first rotating shaft seat 124 and the second rotating shaft seat 125 may be in an integrally formed structure, that is, the rotating shaft 121, the first rotating shaft seat 124 and the second rotating shaft seat 125 are in an integrally formed structure, and the rotating shaft 121, the first rotating shaft seat 124 and the second rotating shaft seat 125 are different parts of the same component. Of course, the rotating shaft 121, the first rotating shaft seat 124 and the second rotating shaft seat 125 may also be fixed connection structures, that is, the first rotating shaft seat 124 is fixed on the first extension portion 1212 of the rotating shaft 121, and the second rotating shaft seat 125 is fixed on the second extension portion 1213 of the rotating shaft 121.

The first rotating shaft seat 124 is located at a side of the first panel 1141 facing away from the ice moving cavity 111, and the first rotating shaft seat 124 is used for disposing the first panel 1141 at a side of the first rotating shaft seat 124 facing toward the ice moving cavity 111. The second rotating shaft seat 125 is located at a side of the second panel 1151 facing away from the ice moving cavity 111, and the second rotating shaft seat 125 is configured to set the second panel 1151 at a side of the second rotating shaft seat 125 facing toward the ice moving cavity 111, so that the first panel 1141 and the second panel 1151 are relatively disposed at two sides of the ice moving body 123.

The specific arrangement of the first panel 1141 on the first rotating shaft seat 124 according to the present application includes, but is not limited to, the following ways:

In some embodiments, one of the first panel 1141 and the first rotating shaft seat 124 is provided with a first positioning groove, and the other is provided with a first positioning block matched with the first positioning groove, and the first positioning block is embedded in the first positioning groove. In other embodiments, one of the first panel 1141 and the first rotating shaft seat 124 is provided with a first magnetic attraction member, and the other is provided with a second magnetic attraction member matched with the first magnetic attraction member, so that the first panel 1141 can be disposed on the first rotating shaft seat 124 by means of magnetic attraction. In still other embodiments, one of the first panel 1141 and the first shaft seat 124 is provided with a first hook and loop fastener fitting, the other is provided with a second hook and loop fastener fitting matched with the first hook and loop fastener fitting, the first panel 1141 is arranged on the first shaft seat 124 through the matching of the first hook and loop fastener fitting and the second hook and loop fastener fitting, or one of the first panel 1141 and the first shaft seat 124 is provided with a first clamping groove, the other is provided with a first buckle matched with the first clamping groove, the first panel 1141 is arranged on the first shaft seat 124 through the buckling of the first clamping groove and the first buckle, or one of the first panel 1141 and the first shaft seat 124 is provided with a first sucker, the first sucker is used for adsorbing the other, and the first panel 1141 is arranged on the first shaft seat 124 through the sucking disc adsorption.

Specific embodiments of the present application for disposing the second panel 1151 on the second pivot base 125 include, but are not limited to, the following:

In some embodiments, one of the second panel 1151 and the second pivot seat 125 is provided with a second positioning groove, and the other is provided with a second positioning block matched with the second positioning groove, and the second positioning block is embedded in the second positioning groove. In other embodiments, one of the second panel 1151 and the second rotating shaft seat 125 is provided with a third magnetic attraction member, and the other is provided with a fourth magnetic attraction member matched with the third magnetic attraction member, so that the second panel 1151 can be disposed on the second rotating shaft seat 125 by means of magnetic attraction. In still other embodiments, one of the second panel 1151 and the second pivot seat 125 is provided with a third hook and loop fastener fitting, the other is provided with a fourth hook and loop fastener fitting matched with the third hook and loop fastener fitting, the second panel 1151 is arranged on the second pivot seat 125 through the matching of the third hook and loop fastener fitting and the fourth hook and loop fastener fitting, or one of the second panel 1151 and the second pivot seat 125 is provided with a second clamping groove, the other is provided with a second clamping buckle matched with the second clamping groove, the second panel 1151 is arranged on the second pivot seat 125 through the buckling of the second clamping groove and the second clamping buckle, or one of the second panel 1151 and the second pivot seat 125 is provided with a second sucker, the second sucker is used for adsorbing the other, and the second panel 1151 is arranged on the second pivot seat 125 through the sucking disc adsorption.

In some embodiments, referring to fig. 7, fig. 7 is a schematic perspective view of another embodiment of an ice-moving device according to the present application. The ice moving device 100 further includes a support plate 130. The support plate 130 is located on a side of the second pivot seat 125 facing away from the second panel 1151. The rotating shaft 121 is rotatably disposed on the supporting plate 130, and the rotating shaft 121 is used for driving the ice moving body 123, the first panel 1141 and the second panel 1151 to rotate.

The support plate 130 is provided with a mounting hole for mounting the rotation shaft 121. The mounting hole is provided with an anti-wear ring 131. The anti-wear ring 131 is clamped in the mounting hole, and the aperture of the anti-wear ring 131 is at least larger than the diameter of the second extension portion 1213 of the rotating shaft 121, so that the second extension portion 1213 can pass through the anti-wear ring 131 and rotate in the anti-wear ring 131, and the rotating friction force between the rotating shaft 121 and the supporting plate 130 is reduced. The ice moving device 100 further includes a driving member (not shown) that may be disposed outside the ice moving cavity 111, and an output shaft of the driving member is coaxially fixed to the rotating shaft 121, where the driving member may be used to drive the rotating shaft 121 to rotate, so that the rotating shaft 121 drives the ice moving body 123, the first panel 1141 and the second panel 1151 to rotate. The rotation of the ice moving member 120 may be controlled by the driving member, and in particular, the driving member may control the rotation start and stop of the ice moving member 120, the rotation direction of the ice moving member 120, and the rotation speed of the ice moving member 120.

The second side plate body 1152 and/or the bottom case 117 of the second side plate 115 are provided to the support plate 130. The second side plate body 1152 and/or bottom shell 117 may be provided to the support plate 130 in a manner including, but not limited to, riveting, bonding, bolting, welding, magnetically attractive attachment.

In some embodiments, the ice moving part 110 further includes a top cover 116 connected between the first and second side plates 114 and 115, and a bottom case 117 surrounding the first and second side plates 114 and 115 at three sides. The first side plate 114, the second side plate 115, the top cover 116, and the bottom case 117 are closed to form the ice moving chamber 111.

The top cover 116 and bottom cover 117 may also be part of the housing of the ice displacement device 100. That is, the first side plate 114, the second side plate 115, the top cover 116 and the bottom cover 117 may serve as a housing of the ice moving device 100, and may perform a bearing and protecting function on the ice moving member 120 of the ice moving device 100.

The top cover 116 is positioned at the top of the ice moving part 110 and between the ice moving inlet 112 and the ice moving outlet 113. The bottom case 117 surrounds the first and second side plates 114 and 115 from the bottom of the ice moving part 110, the sides of the first and second side plates 114 and 115 toward the ice moving inlet 112, and the sides of the first and second side plates 114 and 115 toward the ice moving outlet 113. The surface of the bottom case 117 facing the ice moving chamber 111 is a curved surface, which protrudes in a direction facing away from the ice moving chamber 111. The curved surface is a guide surface of the ice cubes, and the ice cubes can be more smoothly moved in the ice moving chamber 111 under the guide of the curved surface. The curved surface is in smooth transition.

In some embodiments, the ice displacement device 100 further includes an ice filtering section 140. The ice filtering area 140 is located at the bottom of the ice moving part 110. The ice filtering section 140 extends in a direction from the ice moving inlet 112 toward the ice moving outlet 113, and the ice filtering section 140 serves to filter crushed ice and/or water in the ice moving chamber 111.

The ice filtering area 140 has a first through groove 141 communicating with the ice transferring chamber 111. The ice filtering area 140 is located at the bottom of the ice moving portion 110, that is, the first through groove 141 is formed at the bottom of the ice moving portion 110, and the first through groove 141 can allow crushed ice to pass through but not whole ice to pass through. After the ice cubes enter the ice moving cavity 111, the ice moving piece 120 which rotates at a high speed can drive the ice cubes to move, broken ice can pass through the first through groove 141 under the action of centrifugal force, and can fall out of the ice moving cavity 111 from the first through groove 141 when the broken ice passes through the first through groove 141 under the action of gravity, so that the broken ice is filtered, and the broken ice is prevented from being accumulated in the ice moving cavity 111, and therefore the problem that the broken ice is melted and then is condensed again in a low-temperature environment to cause the ice moving piece 120 and other moving parts to be frozen is avoided.

Referring to fig. 8, fig. 8 is a schematic perspective view of another embodiment of an ice-moving device according to the present application, and meanwhile, fig. 6 is continued. The ice displacement device 100 also includes a filter assembly 160. The filter assembly 160 includes a stopper 161 and an ice crushing box 162. The stopper 161 is provided in the first through groove 141. The ice bank 162 is located below the ice moving part 110. At least a portion of the ice moving part 110 is accommodated in the ice crushing box 162, and at least a portion of the first through groove 141 is positioned in the ice crushing box 162. The ice crushing box 162 communicates with the ice moving chamber 111 through the first through groove 141. The ice crushing box 162 is positioned below the ice moving part 110, so that crushed ice falls into the ice crushing box 162 under the action of gravity and the ice moving member 120.

After the stopper 161 intercepts the crushed ice, the crushed ice falls into the crushed ice bin 162 from the first through groove 141. The stopper 161 is a member that easily intercepts crushed ice and easily drops the crushed ice out of the stopper 161 into the ice bank 162, and the stopper 161 may be a brush. The material of the stopper 161 may be selected from waterproof materials. The filter assembly 160 also includes a vibrating member (not shown). The vibration member is provided to the stopper 161. The vibration member is used to drive the stopper 161 to vibrate so that crushed ice intercepted by the stopper 161 is rapidly separated from the stopper 161 and falls into the ice crushing box 162.

The ice crushing box 162 is disposed at the outside of the ice moving part 110, so that crushed ice collected by the ice crushing box 162 is conveniently cleaned. In some embodiments, the ice crushing box 162 is detachably disposed below the ice moving part 110, and when the crushed ice in the ice crushing box 162 reaches a certain amount, the ice crushing box 162 can be taken out, and after the crushed ice is cleaned, the ice crushing box 162 is disposed on the ice moving part 110. The box body of the ice crushing box 162 can be colorless and transparent, so that the collection degree of crushed ice in the ice crushing box 162 can be conveniently observed, and the situation that crushed ice in the ice moving cavity 111 cannot fall out from the first through groove 141 to be accumulated in the ice moving cavity 111 after the ice crushing box 162 is full of crushed ice is avoided.

The first through groove 141 has a first wall 1411 and a second wall 1412 which are disposed opposite to each other. The stopper 161 is provided to the first wall 1411 and/or the second wall 1412. Of course, the stopper 161 may be disposed between the first wall 1411 and the second wall 1412, the stopper 161 being spaced apart from the first wall 1411, and the stopper 161 being spaced apart from the second wall 1412, so as to facilitate the passage of crushed ice and/or water.

The bottom housing 117 includes a first bottom plate 1171 and a second bottom plate 1172 connected. The side of the first bottom plate 1171 remote from the second bottom plate 1172 is connected to the first side plate 114. The side of the second bottom plate 1172 remote from the first bottom plate 1171 is connected to the second side plate 115. The first bottom plate 1171 and the second bottom plate 1172 can be of unitary construction. The first through groove 141 is formed on a side of the first bottom plate 1171 and the second bottom plate 1172 away from the ice moving inlet 112 and the ice moving outlet 113.

The first bottom plate 1171 has a first sub-slot 1171a. The second bottom plate 1172 has a second sub-slot 1172a. The first and second sub-grooves 1171a and 1172a penetrate to form a first through groove 141. The first sub-slot 1171a extends from the edge of the first bottom plate 1171 adjacent to the first side plate 114 to the edge of the first bottom plate 1171 adjacent to the second bottom plate 1172, the second sub-slot 1172a extends from the edge of the second bottom plate 1172 adjacent to the second side plate 115 to the edge of the second bottom plate 1172 adjacent to the first bottom plate 1171, i.e., the first through-slot 141 extends from the edge of the first side plate 114 to the edge of the second side plate 115. The first through groove 141 has an arc shape.

The ice moving part 110 further has a second through groove 142 communicating with the ice moving chamber 111. The second through groove 142 is opened in the bottom case 117 and extends in the first direction X, and crushed ice is easily dropped out of the second through groove 142. The positional relationship between the second through-grooves 142 and the first through-grooves 141 may be determined according to the actual situation, and is not particularly limited, and for example, the second through-grooves 142 may be opened between adjacent first through-grooves 141, and the second through-grooves 142 may or may not be in communication with the first through-grooves 141.

Through set up first through groove 141 and second through groove 142 at ice filtering area 140, be convenient for move ice piece 120 and throw away broken ice from first through groove 141 and second through groove 142 to can carry out more thorough filtering to broken ice, prevent that broken ice from piling up, improved ice filtering efficiency and ice filtering effect.

In some embodiments, the ice moving body 123 is selected from bristles or fan blades.

The ice moving body 123 may be selected from fan blades. The blades are radially unfolded toward the outer circumference of the rotation shaft 121 by the shaft sleeve 122 and/or the rotation shaft body 1211. The fan blades extend from the end of the shaft sleeve 122 and/or the shaft body 1211 adjacent the first panel 1141 to the end adjacent the second panel 1151. The fan blade extends in a direction perpendicular to the plane of the first and second panels 1141 and 1151. An ice carrying groove 123a is arranged between the adjacent fan blades, the ice carrying groove 123a is used for containing ice cubes entering the ice moving cavity 111 from the ice moving inlet 112, and the fan blades are used for driving the ice cubes of the ice carrying groove 123a to be thrown out towards the ice moving outlet 113. Through forming ice-carrying groove 123a between the flabellum for the ice-cube can get into different ice-carrying groove 123a one by one, makes can not bump between the ice-cube, and is difficult for appearing melting the circumstances of adhesion, thereby realizes separating the ice-cube, has improved ice-cube quality. The fan blades can be flexible fan blades, and the fan blades can deform to a certain extent after being extruded by ice cubes, so that the ice cubes are conveniently contained in the ice carrying groove 123 a.

The ice moving body 123 may be selected from bristles. After the ice cubes enter the ice moving cavity 111 through the ice moving outlet 113, the ice cubes can squeeze the bristles, the bristles are deformed due to the squeezing of the ice cubes, gaps capable of containing the ice cubes are formed, and meanwhile the bristles can carry the ice cubes to move and throw the ice cubes out through the ice moving outlet 113.

Because the first panel 1141 and the second panel 1151 can rotate along with the ice moving member 120, even if the ice moving body 123 is deformed to contact the first panel 1141 and/or the second panel 1151 by the compression of ice cubes, the ice moving body 123 does not interfere with the first panel 1141 and/or the second panel 1151, thereby protecting the ice moving body 123, the first panel 1141 and the second panel 1151.

In some embodiments, referring to fig. 9, fig. 9 is a schematic structural diagram of an ice-moving device according to another embodiment of the present application, and meanwhile, referring to fig. 3. The ice moving part 110 further includes a pressing plate 150. The pressing plate 150 is disposed on the top cover 116 and located in the ice moving cavity 111. The shortest distance between the end of the pressing plate 150 facing the ice moving member 120 and the central axis of the ice moving member 120 is smaller than the radius of the ice moving member 120.

During the rotation of the ice moving member 120, the ice moving body 123 is deformed in contact with the pressing plate 150, and a relief port 151 is formed at the ice moving inlet 112. The pressing plate 150 presses part of the ice moving body 123, and along with the rotation of the ice moving member 120, ice cubes are easily brought into the ice moving member 120 at the yielding port 151 when entering the ice moving cavity 111 through the ice moving inlet 112, so that the ice moving efficiency of the ice moving device 100 is improved, and the ice cubes are prevented from being blocked at the ice moving inlet 112. It should be noted that, no matter the ice moving body 123 is selected from a brush or a fan blade, under the action of the pressing plate 150, the abdication opening 151 can be formed at the ice moving inlet 112.

The present application also provides a refrigeration appliance 10. Referring to fig. 10, fig. 10 is a schematic perspective view of a refrigeration apparatus according to the present application. The refrigeration appliance 10 includes at least an ice displacement device 100 and an ice extraction assembly 200. In the present embodiment, the manner in which the ice moving device 100 is provided to the refrigeration apparatus 10 is not limited. Referring to the above embodiment for the specific structure of the ice-moving device 100, since the refrigeration equipment 10 provided by the present application adopts all the technical solutions of the ice-moving device 100, at least the technical solutions of the above embodiment have all the beneficial effects, and will not be described in detail herein.

The application provides an ice moving device and refrigeration equipment, wherein the ice moving device is used for the refrigeration equipment and comprises an ice moving part, an ice moving piece, a first panel and a second panel, wherein the ice moving part is provided with an ice moving cavity, the ice moving part comprises a first side plate and a second side plate which are oppositely arranged, the ice moving piece can be rotatably arranged in the ice moving cavity, the first panel is a part of the first side plate, the second panel is a part of the second side plate, the first panel is arranged on one side of the ice moving piece, the second panel is arranged on the other side of the ice moving piece, the first panel and the second panel rotate along with the ice moving piece, and the ice moving piece cannot rub the first panel and/or the second panel, so that the ice moving piece can be prevented from rubbing the first side plate and/or the second side plate on the premise that the distance between the ice moving piece and the first side plate and the distance between the ice moving piece and the second side plate are not required to be enlarged.

The foregoing description is only of embodiments of the present application, and is not intended to limit the scope of the application, and all equivalent structures or equivalent processes using the descriptions and the drawings of the present application or directly or indirectly applied to other related technical fields are included in the scope of the application.

Claims (12)

1. An ice-moving device for setting up in refrigeration plant, its characterized in that moves ice-moving device and includes:

The ice moving part is provided with an ice moving cavity and comprises a first side plate and a second side plate which are oppositely arranged;

The ice moving piece is rotatably arranged in the ice moving cavity;

The first panel is a part of the first side plate, the second panel is a part of the second side plate, the first panel is arranged on one side of the ice moving piece, the second panel is arranged on the other side of the ice moving piece, and the first panel and the second panel rotate along with the ice moving piece.

2. The ice moving device of claim 1, wherein the ice moving portion further has an ice moving inlet and an ice moving outlet in communication with the ice moving chamber, the ice moving member being configured to rotate in a first direction for driving ice cubes entering the ice moving chamber from the ice moving inlet to be ejected toward the ice moving outlet.

3. The ice-moving device of claim 1, wherein the ice-moving member comprises a rotary shaft and an ice-moving body, the rotary shaft comprises a rotary shaft main body, a first extension part and a second extension part, the rotary shaft main body is positioned between the first extension part and the second extension part, and the ice-moving body is arranged on the rotary shaft main body.

4. The ice removing device of claim 3, wherein said ice removing member further comprises a sleeve, said sleeve is sleeved on said shaft body, said first extension and said second extension are exposed to said sleeve, said ice removing body is disposed on said sleeve, or on said sleeve and said shaft body.

5. The ice-moving device according to claim 3, wherein the first extension portion is disposed through the first panel, the second extension portion is disposed through the second panel, and the ice-moving body is disposed between the first panel and the second panel.

6. The ice-moving device according to claim 3, wherein the ice-moving member further comprises a first rotating shaft seat and a second rotating shaft seat, the first rotating shaft seat is arranged on the first extension portion, the first rotating shaft seat is positioned on one side of the first panel, which is opposite to the ice-moving cavity, the second rotating shaft seat is arranged on the second extension portion, and the second rotating shaft seat is positioned on one side of the second panel, which is opposite to the ice-moving cavity.

7. The ice-moving device according to claim 6, further comprising a support plate, wherein the support plate is located at a side of the second rotating shaft seat facing away from the second panel, the rotating shaft is rotatably disposed on the support plate, and the rotating shaft is used for driving the ice-moving body, the first panel and the second panel to rotate.

8. The ice-moving device of claim 4, wherein the ice-moving body is selected from the group consisting of bristles and fan blades.

9. The ice-moving device of claim 2, wherein the ice-moving portion further comprises a top cover connected between the first side plate and the second side plate, and a bottom shell surrounding the first side plate and the second side plate on three sides, the first side plate, the second side plate, the top cover, and the bottom shell enclosing to form the ice-moving cavity.

10. The ice displacement device of claim 9, further comprising an ice filtering area at the bottom of the ice displacement portion, the ice filtering area extending in a direction from the ice displacement inlet toward the ice displacement outlet, the ice filtering area for filtering crushed ice and/or water in the ice displacement cavity.

11. The ice-moving device according to claim 9, wherein the ice-moving part further comprises a pressing plate, the pressing plate is arranged on the top cover and positioned in the ice-moving cavity, and the shortest distance between the end of the pressing plate, which faces the ice-moving part, and the central axis of the ice-moving part is smaller than the radius of the ice-moving part.

12. A refrigeration apparatus comprising an ice-moving device according to any one of claims 1 to 11.