阅读说明：本技术 具有铰接的测隙规臂的制冰机 (Ice maker with hinged feeler gauge arm ) 是由 C·F·伯德 于 2019-06-17 设计创作，主要内容包括：一种用于冷藏器具的制冰机(100)包括具有轴(112)的马达(110)。测隙规臂联轴器(120)连接到马达(110)的轴(112)。马达(110)可操作以绕旋转轴线旋转测隙规臂联轴器(120)。测隙规臂耙(130)铰接到测隙规臂联轴器(120),使得测隙规臂耙(130)可相对于测隙规臂联轴器(120)绕铰链轴线旋转。铰链轴线垂直于旋转轴线。当马达(110)操作以旋转测隙规臂联轴器(120)时,测隙规臂耙(130)随着测隙规臂联轴器(120)绕旋转轴线旋转。(An ice maker (100) for a refrigeration appliance includes a motor (110) having a shaft (112). A feeler gauge arm coupling (120) is connected to the shaft (112) of the motor (110). The motor (110) is operable to rotate the feeler gauge arm coupling (120) about a rotational axis. The feeler arm rake (130) is hinged to the feeler arm coupling (120) such that the feeler arm rake (130) is rotatable about a hinge axis with respect to the feeler arm coupling (120). The hinge axis is perpendicular to the rotation axis. When the motor (110) operates to rotate the feeler gauge arm coupling (120), the feeler gauge arm rake (130) rotates about the axis of rotation with the feeler gauge arm coupling (120).)

1. An ice maker for a refrigeration appliance, comprising:

a motor having a shaft;

a feeler gauge arm coupling connected to a shaft of the motor, the motor operable to rotate the feeler gauge arm coupling about a rotational axis; and

a feeler gauge arm rake hinged to the feeler gauge arm coupling such that the feeler gauge arm rake is rotatable with respect to the feeler gauge arm coupling about a hinge axis, the hinge axis being perpendicular to the rotation axis,

wherein when the motor is operated to rotate the feeler gauge arm coupling, the feeler gauge arm rake rotates with the feeler gauge arm coupling about the axis of rotation.

2. The ice-making machine of claim 1, further comprising a mold body, said feeler gauge arm rake positioned below said mold body.

3. The ice maker of claim 1, wherein the feeler arm rake includes an elongated plate and a sweep plate, and the sweep plate extends downwardly from the elongated plate.

4. The ice maker of claim 3, wherein the feeler gauge arm rake includes a plurality of lift plates extending downwardly from the elongated plate, and the plurality of lift plates are distributed along a transverse direction perpendicular to the rotational axis and the hinge axis.

5. The ice maker of claim 4, wherein each of the plurality of lift plates has an arcuate bottom surface.

6. The ice maker of claim 1, wherein the feeler gauge arm rake is rotatable on the hinge axis between a rest position and a raised position.

7. The ice maker of claim 6, further comprising a hinge connecting the feeler arm rake to the feeler arm coupling, the hinge comprising a pair of hinge arms mounted to one of the feeler arm rake and the feeler arm coupling and a hinge post positioned between the pair of hinge arms and mounted to the other of the feeler arm rake and the feeler arm coupling.

8. The ice maker of claim 7, wherein the hinge further comprises a spring urging the feeler arm rake toward the rest position.

9. The ice maker as in claim 1, wherein the feeler gauge arm coupling defines a lug interface into which the shaft of the motor is received.

10. The ice maker of claim 1, further comprising a bucket movable relative to the feeler arm rake, the feeler arm rake rotating on the hinge axis from a rest position to a raised position when a lip of the bucket is positioned below the feeler arm rake.

11. A refrigeration container appliance comprising:

a housing defining a cooling chamber;

an ice maker positioned within or on a door of the housing, the ice maker comprising

A motor having a shaft;

a feeler gauge arm coupling connected to a shaft of the motor, the motor operable to rotate the feeler gauge arm coupling about a rotational axis; and

a feeler gauge arm rake hinged to the feeler gauge arm coupling such that the feeler gauge arm rake is rotatable with respect to the feeler gauge arm coupling about a hinge axis, the hinge axis being perpendicular to the rotation axis,

wherein when the motor is operated to rotate the feeler gauge arm coupling, the feeler gauge arm rake rotates with the feeler gauge arm coupling about the axis of rotation.

12. The refrigeration container appliance of claim 11 wherein said ice maker further comprises a mold body, said feeler gauge arm rake positioned below said mold body.

13. The refrigeration container appliance of claim 11 wherein said feeler arm rake includes an elongated plate and a sweep plate, and said sweep plate extends downwardly from said elongated plate.

14. The cooler appliance of claim 13, wherein said feeler arm rake comprises a plurality of lift plates extending downwardly from said elongated plate and distributed along a transverse direction perpendicular to said rotational axis and said hinge axis.

15. The refrigeration container appliance of claim 14 wherein each of said plurality of lift plates has an arcuate bottom surface.

16. The refrigeration container appliance of claim 11 wherein said feeler arm rake is rotatable on said hinge axis between a rest position and a raised position.

17. The refrigeration container appliance of claim 16 wherein said ice maker further comprises a hinge connecting said feeler arm rake to said feeler arm coupling, said hinge comprising a pair of hinge arms mounted to one of said feeler arm rake and said feeler arm coupling and a hinge post positioned between said pair of hinge arms and mounted to the other of said feeler arm rake and said feeler arm coupling.

18. The cooler appliance of claim 17, wherein said hinge further comprises a spring urging said feeler arm rake toward said rest position.

19. The cooler appliance of claim 11, wherein said feeler gauge arm coupling defines a lug interface into which said shaft of said motor is received.

20. The refrigeration container appliance of claim 11 wherein said ice maker further comprises a bucket, said bucket being movable relative to said feeler arm rake, said feeler arm rake rotating on said hinge axis from a rest position to a raised position when a lip of said bucket is positioned below said feeler arm rake.

Technical Field

The present subject matter relates generally to ice makers and feeler gauge arms for ice makers.

Background

Some refrigeration container appliances include an ice maker. The ice maker operates to produce ice for consumption. In particular, known ice makers operate to generate ice cubes, and the ice cubes taken out of the ice maker are stored in a tub. To avoid excessive ice formation, a feeler gauge arm is swept across the ice bucket. When the ice bucket is filled to a certain height, the feeler gauge arm can impact ice blocks on the ice bucket. Thus, the feeler gauge arm operates to determine when the ice bucket is full.

The known feeler gauge arm has drawbacks. For example, such a feeler gauge arm sweeps over the top edge of an ice bucket. Thus, such a feeler gauge arm would take up valuable vertical space above the ice bucket, and ice cubes would have to fill the ice bucket above the top edge of the ice bucket in order for the feeler gauge arm to strike the ice cubes and detect that the ice bucket is full. It may be disadvantageous for the tub above the top edge of the ice bucket to be filled with ice cubes. For example, ice cubes are easily spilled from an ice bucket whenever the ice bucket is moved.

Disclosure of Invention

Aspects and advantages of the invention will be set forth in part in the following description, or may be obvious from the description, or may be learned through practice of the invention.

In a first exemplary embodiment, an ice maker for a refrigeration appliance includes a motor having a shaft. The feeler gauge arm coupling is connected to the shaft of the motor. The motor is operable to rotate the feeler gauge arm coupling about the axis of rotation. The feeler arm rake is hinged to the feeler arm coupling such that the feeler arm rake can rotate about the hinge axis with respect to the feeler arm coupling. The hinge axis is perpendicular to the rotation axis. When the motor operates to rotate the feeler gauge arm coupling, the feeler gauge arm rake rotates about the axis of rotation with the feeler gauge arm coupling.

In a second exemplary embodiment, a cooler appliance includes an outer shell defining a cooling chamber. The ice maker is positioned within the housing or on a door of the housing. The ice maker includes a motor having a shaft. The feeler gauge arm coupling is connected to the shaft of the motor. The motor is operable to rotate the feeler gauge arm coupling about the axis of rotation. The feeler arm rake is hinged to the feeler arm coupling such that the feeler arm rake can rotate about the hinge axis with respect to the feeler arm coupling. The hinge axis is perpendicular to the rotation axis. When the motor operates to rotate the feeler gauge arm coupling, the feeler gauge arm rake rotates about the axis of rotation with the feeler gauge arm coupling.

These and other features, aspects, and advantages of the present invention will become better understood with reference to the following description and appended claims. The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description, serve to explain the principles of the invention.

Drawings

A full and enabling disclosure of the present invention, including the best mode thereof, directed to one of ordinary skill in the art, is set forth in the specification, which makes reference to the appended figures.

FIG. 1 is a front view of a cylindrical refrigeration case appliance and a cylindrical freezer appliance according to an exemplary embodiment of the present subject matter.

Fig. 2 and 3 are side views of ice makers according to example embodiments of the present subject matter.

FIG. 4 is a bottom perspective view of a feeler gauge arm of the example ice maker of FIG. 2.

FIG. 5 is a partial perspective view of the hinge of the feeler gauge arm of FIG. 4.

Fig. 6-8 are schematic views of the example ice maker of fig. 2, showing an ice bucket in different positions relative to a feeler gauge arm of the example ice maker.

Detailed Description

Reference now will be made in detail to embodiments of the invention, one or more examples of which are illustrated in the drawings. Each example is provided by way of explanation of the invention, not limitation of the invention. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope or spirit of the invention. For instance, features illustrated or described as part of one embodiment, can be used with another embodiment to yield a still further embodiment. Thus, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

FIG. 1 is a front view of a refrigeration appliance, including a cylindrical refrigeration case appliance 10 and a cylindrical freezer appliance 20 according to an exemplary embodiment of the present subject matter. As can be seen in FIG. 1, the cylindrical refrigeration case appliance 10 and/or the cylindrical freezer appliance 20 may be positioned within a set of cabinets 30. The front panel 12 on the door 13 of the cylindrical refrigeration case appliance 10 and/or the front panel 22 on the door 23 of the cylindrical freezer appliance 20 may mate with the front panel 32 of the cabinet 30. Thus, the cylindrical refrigeration case appliance 10 and the cylindrical freezer appliance 20 can match the appearance of the cabinet 30. It should be understood that the cylindrical refrigeration case appliance 10 and the cylindrical freezer appliance 20 are provided by way of example only. Other configurations of the refrigeration appliance are also within the scope of the present subject matter. For example, the present subject matter may be used with and/or with appliances having freezer compartments and cooling compartments, freezer compartments only, cooling compartments only, or other combinations thereof other than those shown in fig. 1.

As can be seen in FIG. 1, the cylindrical cooler appliance 10 is depicted as an upright cooler having an outer shell 14 defining an internally cooled fresh food compartment 16, while the cylindrical freezer appliance 20 is depicted as an upright freezer having an outer shell 24 defining an internally cooled freezer compartment 26. Each of the cylindrical refrigerator appliance 10 and the cylindrical freezer appliance 20 further includes a respective heat pump system (not shown) for removing heat from the internally cooled fresh food compartment 14 and the internally cooled freezer compartment 24. As will be understood by those skilled in the art, the heat pump systems may each include a compressor, a condenser, an expansion device, and an evaporator connected in series and charged with a refrigerant.

An ice maker 40 is positioned within the freezer compartment 26. Ice maker 40 is operable to generate ice for consumption. It should be understood that in alternative exemplary embodiments, the ice maker 40 may be positioned within the cylindrical refrigeration case appliance 10. Further, it should be understood that in alternative exemplary embodiments, the ice maker 40 may be mounted on the door 23.

Fig. 2 and 3 are side views of ice making machine 100 according to example embodiments of the present subject matter. The ice-making machine 100 can be used with or as a cylindrical refrigeration case appliance 10 and/or a cylindrical freezer appliance 20 of the ice-making machine 40. Thus, the ice maker 100 may be positioned in the housing 14 of the cylindrical refrigeration case appliance 10 or the housing 24 of the cylindrical freezer appliance 20. Ice maker 100 will be described in more detail below in the context of a cylindrical freezer appliance 20. However, it should be understood that ice-making machine 100 could also be used in any other suitable refrigeration appliance.

The ice maker 100 includes a motor 110 having a shaft 112. The motor 110 is operable to rotate a shaft 112. For example, the motor 110 may be operable to rotate the shaft 112 through an appropriate fraction of one or more arcs in a first rotational direction and through the same fraction of one or more arcs in a second rotational direction. Further, the motor 110 is operable to sequentially rotate the shaft 112 in a first rotational direction and a second rotational direction.

The ice-making machine 100 also includes a gauge arm coupling 120 and a gauge arm rake 130. The feeler arm coupling 120 and the feeler arm rake 130 together form a feeler arm of the ice maker 100. The feeler gauge arm coupling 120 is connected to the shaft 112 of the motor 110. The motor 110 is operable to rotate the feeler gauge arm coupling 120 about the axis of rotation R. In particular, the motor 110 is operable to rotate the feeler gauge arm coupling 120 about the axis of rotation R in the same or similar manner as described above for the shaft 112. The feeler arm coupling 120 may be connected to the shaft 112 by inserting the shaft 112 into the feeler arm coupling 120. For example, the feeler gauge arm coupling 120 may define a lug interface 122 (fig. 5), and the shaft 112 of the motor 110 may be received within the lug interface 122. The lug interface 122 may be shaped such that interference between the shaft 112 of the motor 110 and the feeler gauge arm coupling 120 at the lug interface 122 may rotationally fix the shaft 112 to the feeler gauge arm coupling 120.

The feeler arm rake 130 is hinged to the feeler arm coupling 120. In particular, the feeler arm rake 130 is hinged to the feeler arm coupling 120 such that the feeler arm rake 130 is rotatable about a hinge axis H (shown in fig. 4 and extending in and out of the page in the perspective views of fig. 2 and 3) with respect to the feeler arm coupling 120. The hinge axis H is perpendicular to the rotation axis R. It should be appreciated that in certain example embodiments, the hinge axis H need not be oriented exactly ninety degrees (90 °) from the rotational axis R. Rather, the term "perpendicular" as used herein includes a margin of ten degrees (i.e., 90 ° ± 10 °). Thus, the hinge axis H may be oriented substantially perpendicular to the rotation axis R. The feeler arm rake 130 may also be connected to the feeler arm coupling 120 such that when the motor 110 is operated to rotate the feeler arm coupling 120, the feeler arm rake 130 rotates about the rotation axis R with the feeler arm coupling 120.

The feeler gauge arm rake 130 is rotatable on the hinge axis H between a rest position (shown in fig. 2) and a raised position (shown in fig. 3). As discussed in more detail below, moving the feeler arm rake 130 from the rest position to the raised position can allow the ice bucket 150 (fig. 6-8) to move relative to the feeler arm rake 130 without the feeler arm rake 130 impeding such movement. Thus, the hinged connection between the feeler gauge arm coupling 120 and the feeler gauge arm rake 130 may advantageously facilitate movement of the feeler gauge arm rake 130 relative to the ice bucket 150.

The ice-making machine 100 also includes a mold body 140. The die body 140 is configured to receive a flow of liquid water. Within the mold block 140, liquid water may freeze within the mold block 140 to form ice cubes. Ice pieces may be removed from the mold body 140 and directed into the ice bucket 150. The feeler gauge arm rake 130 may be positioned below the die body 140. As the motor 110 rotates the feeler arm rake 130, the feeler arm rake 130 may sweep over the ice bucket 150. As the feeler arm rake 130 sweeps over the ice bucket 150, the feeler arm rake 130 can strike ice cubes within the ice bucket 150 when the ice bucket 150 is properly filled with ice cubes. In this manner, the feeler gauge arm rake 130 can be used to detect when the ice bucket 150 is properly filled with ice cubes.

FIG. 4 is a bottom perspective view of a feeler gauge arm of the ice maker 100. As can be seen in fig. 4, the feeler arm rake 130 includes an elongated plate 132 and a sweep plate 134. The elongated plate 132 extends radially (e.g., relative to the rotational axis R) away from the feeler-arm coupling 120 along the length of the elongated plate 132. The sweep plate 134 is mounted to the elongated plate 132 and extends downwardly from the elongated plate 132. The sweep plate 134 may also extend radially (e.g., relative to the rotational axis R) along the length of the sweep plate 134 away from the feeler arm coupling 120. As the feeler gauge arm rake 130 sweeps across the ice bucket 150 in the manner described above, the sweep plate 134 can strike ice pieces within the ice bucket 150.

The feeler gauge arm rake 130 can also include a plurality of lift plates 136. A lift plate 136 extends downwardly from the elongated plate 132. The lift plates 136 may also be distributed along a transverse direction T (e.g., perpendicular to the rotation axis R and the hinge axis H). The lift plate 136 can be shaped to ride on the ice bucket 150 as the feeler gauge arm rake 130 moves from the rest position to the lift position. As one example, each lift plate 136 may have an arcuate bottom surface 138. The arcuate floor 138 may strike the ice bucket 150 and slide upward as the feeler arm rake 130 moves from the rest position to the raised position. As another example, each lift plate 136 may have a suitably sloped bottom surface 138. The lift plate 136 may also be oriented perpendicular to the sweep plate 134 on the elongated plate 132, as shown in FIG. 4.

Figure 5 is a partial perspective view of the hinge 160 of the feeler gauge arm. The hinge 160 may connect the feeler arm rake 130 to the feeler arm coupling 120 such that the feeler arm rake 130 is rotatable about the hinge axis H relative to the feeler arm coupling 120. The hinge 160 includes a pair of hinge arms 162 and a hinge post 164. The hinge arm 162 is mounted to one of the feeler arm rake 130 and the feeler arm coupling 120. In fig. 5, the hinge arm 162 is shown mounted to the feeler gauge arm coupling 120. The hinge post 164 is positioned between the hinge arms 162. In addition, a hinge post 164 is mounted to the other of the feeler arm rake 130 and the feeler arm coupling 120. In fig. 5, the hinge post 164 is mounted to the feeler arm rake 130. A shaft (not shown) may extend through the hinge arm 162 and the hinge post 164 to rotatably couple the hinge post 164 to the hinge arm 162.

Hinge 160 also includes a spring 166. The spring 166 urges the feeler arm rake 130 toward a rest position. Thus, the spring 166 may be coupled to the feeler arm rake 130 such that the feeler arm rake 130 is normally in a rest position. In fig. 5, the spring 166 is a coil spring. In alternative exemplary embodiments, the spring 166 may be an extension spring or a compression spring. The distal portion 139 (fig. 4) of the feeler arm rake 130 can also be weighted to help urge the feeler arm rake 130 toward the rest position. It should be appreciated that the distal end portion 139 of the feeler arm rake 130 can move vertically as the feeler arm rake 130 rotates on the hinge axis H.

Fig. 6-8 are schematic views of the ice maker 100 showing the ice bucket 150 in different positions relative to the feeler gauge arm of the ice maker 100. As shown in fig. 6-8, as the ice bucket 150 moves under the feeler arm rake 130, the feeler arm rake 130 moves from a rest position to a raised position. Beginning with fig. 6, the feeler arm rake 130 is in a rest position and the ice bucket 150 is positioned below the feeler arm rake 130. Further, the sweep plate 134 and/or the lift plate 136 may be positioned within the ice bucket 150. In the configuration shown in fig. 6, the feeler gauge arm rake 130 can be used to detect when the ice bucket 150 is properly filled with ice cubes by sweeping over the ice bucket 150 in the manner described above. In particular, the motor 110 is operable to rotate the feeler arm rake 130 about the axis of rotation R so as to sweep the feeler arm rake 130 across the ice bucket 150.

According to the arrangement of FIG. 6, a user of the cylindrical cooler appliance 10 may wish to move the ice bucket 150. Thus, a user may grasp the ice bucket 150 and pull the ice bucket 150 in a direction away from the feeler arm rake 130. In particular, the ice bucket 150 may be removed from beneath the mold body 140 by a user pulling the ice bucket in a removal direction D (e.g., perpendicular to the rotational axis R and/or parallel to the hinge axis H). As used herein, the term "parallel" includes a ten degree margin (i.e., 0 ° ± 10 °).

During movement of the ice bucket 150 in the removal direction D from the position shown in fig. 6, the feeler gauge arm rake 130 strikes the side wall 154 of the ice bucket 150. Due to the shape of the feeler arm rake 130 (e.g., the lift plate 136), the feeler arm rake 130 can slide up the side wall 154 of the ice bucket 150 and rotate on the hinge axis H from a rest position to a raised position, as shown in fig. 7. Thus, for example, when the side wall 154 of the ice bucket 150 is positioned directly below the feeler arm rake 130, the feeler arm rake 130 can be positioned in a raised position. According to fig. 7, the user may continue to pull the ice bucket 150 in the removal direction D until the ice bucket 150 is completely removed from under the feeler gauge arm rake 130, as shown in fig. 8. When the ice bucket 150 is removed from under the feeler arm rake 130, the feeler arm rake 130 can move back to the rest position.

It should be appreciated that the process described above for removing the ice bucket 150 from under the feeler arm rake 130 can be reversed to insert the ice bucket 150 under the feeler arm rake 130. In this manner, the ice bucket 150 may be advantageously removed and inserted under the feeler arm rake 130 without the feeler arm rake 130 catching the ice bucket 150. In particular, hinging the feeler gauge arm rake 130 to the feeler gauge arm coupling 120 such that the feeler gauge arm rake 130 can rotate on the hinge axis H can advantageously allow the sweep plate 134 and/or the lift plate 136 to extend into the ice bucket 150 below the top edge 152 of the ice bucket 150 while still allowing the ice bucket 150 to move freely relative to the feeler gauge arm rake 130 in the removal direction D. Accordingly, the feeler gauge arm rake 130 can strike ice cubes below the top edge 152 of the ice bucket 150 and can avoid or prevent filling the ice bucket 150 with ice cubes above the top edge 152 of the ice bucket 150. By avoiding overfilling of the ice bucket 150, the ice bucket 150 can be removed from beneath the mold body 140 with reduced or no ice spillage from the ice bucket 150.

This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they include structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.