The present disclosure relates generally to a door hinge assembly of a domestic refrigerator and more particularly to a cam plate for a door hinge assembly of a domestic refrigerator.
A domestic refrigerator is a device used to store food items in a home at preset temperatures. A domestic refrigerator typically includes one or more temperature-controlled compartments into which food items may be placed to preserve the food items for later consumption. A domestic refrigerator also typically includes a door that permits user access to the temperature-controlled compartment defined in the refrigerator cabinet. The door may be mounted to the cabinet via a hinge assembly.
According to one aspect of the disclosure, a domestic refrigerator includes a cabinet having a temperature-controlled compartment defined therein, a door positioned at a front of the cabinet, a first cam plate positioned at a first end of the door that includes a first cam surface, and a hinge bracket coupled to the cabinet. The hinge bracket includes a mounting plate and an inner wall that defines a slot through the mounting plate. The refrigerator also includes a second cam plate positioned between the mounting plate and the first cam plate. The second cam plate includes a plate body having a second cam surface engaged with the first cam surface of the first cam plate, and a plug extending from the plate body through the slot defined in the mounting plate. The plug includes a resilient tongue having a catch formed thereon to engage a surface of the mounting plate to prevent removal of the second cam plate from the hinge bracket.
In some embodiments, the domestic refrigerator may include a hinge pin coupled to the hinge bracket and extending through a bore defined in the plate body. Additionally, in some embodiments, the hinge pin may be threadingly coupled to the hinge bracket. When the hinge pin is rotated in a first direction, the door, the first cam plate, and the second cam plate may be moved upward relative to the cabinet. When the hinge pin is rotated in a second direction, the door, the first cam plate, and the second cam plate may be moved downward relative to the cabinet.
In some embodiments, when the hinge pin is rotated in the first direction, the plug may be configured to slide upward along the inner wall of the hinge bracket. In some embodiments, the plug may define a first longitudinal axis and the hinge pin may define a second longitudinal axis offset from and extending parallel to the first longitudinal axis.
In some embodiments, the plug may include an outer surface facing the inner wall of the hinge bracket and a rib extending from the outer surface. The rib may engage the inner wall of the hinge bracket. In some embodiments, the outer surface of the plug may be convex. Additionally, in some embodiments, the slot defined in the mounting plate may be oblong. In some embodiments, the rib of the plug may engage a substantially planar inner wall section of the inner wall, and the resilient tongue may have an outer surface facing a concave inner wall section of the inner wall.
In some embodiments, the resilient tongue may be a first resilient tongue, and the plug may include a second resilient tongue extending parallel to the first resilient tongue. The plug may include a body positioned between the first resilient tongue and the second resilient tongue.
According to another aspect, a refrigerator door hinge assembly is disclosed. The refrigerator door hinge assembly includes a hinge bracket including a mounting plate and an inner wall that defines a slot through the mounting plate, and a cam plate coupled to the hinge bracket. The cam plate includes a plate body having a cam surface configured to engage a corresponding cam surface positioned at a lower end of a refrigerator door, and a plug extending from the plate body through the slot defined in the mounting plate. The refrigerator door hinge assembly also includes a hinge pin moveably coupled to the hinge bracket, and the hinge pin includes a shaft that extends through an opening defined in the plate body. The plug of the cam plate includes a pair of resilient tongues and a body positioned between the resilient tongues. Each resilient tongue has a catch formed thereon to engage a bottom surface of the mounting plate. The body engages the inner wall of the hinge bracket. In some embodiments the engagement of the cam plate to the bracket may be permanently affixed. In some embodiments the engagement of the cam plate to the bracket may be removable with a tool. In some embodiments the engagement of the cam plate to the bracket may be friction mounted.
In some embodiments, the inner wall of the hinge bracket may include a pair of substantially planar wall sections and a pair of concave wall sections connecting the pair of substantially planar wall sections. In some embodiments, the body of the plug may include a first beam including a first convex outer surface facing a first wall section of the pair of substantially planar wall sections, a second beam including a second convex outer surface facing a second wall section of the pair of substantially planar wall sections, and a third beam connecting the first beam to the second beam. Each of the resilient tongues may have an outer surface that faces one of the pair of concave wall sections.
Additionally, in some embodiments, the plug may include a first rib extending from the first convex outer surface. The first rib may be engaged with the first wall section of the hinge bracket. The plug may also include a second rib extending from the second convex outer surface. The second rib may be engaged with the second wall section of the hinge bracket.
According to another aspect, a door cam plate for a domestic refrigerator is disclosed. The door cam plate includes a plate body including an upper surface, a lower surface positioned opposite the upper surface, and a circular bore extending through the upper surface and the lower surface. The door cam plate also includes a pair of curved walls extending upwardly from the upper surface adjacent the circular bore, and a plug extending downwardly from the lower surface of the plate body. Each curved wall includes a cam surface configured to engage a corresponding cam surface positioned at a lower end of a refrigerator door. The plug includes a first resilient tongue having a first catch extending outwardly from a lower end thereof, a second resilient tongue having a second catch extending outwardly from a lower end thereof, and a body positioned between the first resilient tongue and the second resilient tongue.
In some embodiments, the body may include a first beam including a first convex outer surface, a second beam including a second convex outer surface, and a third beam connecting the first beam to the second beam. Additionally, in some embodiments, the plug may include a first rib extending outwardly from the first convex outer surface and a second rib extending outwardly from the second convex outer surface. In some embodiments, the third beam may define an axis, and the first rib and the second rib may be positioned on the axis.
In some embodiments, the first catch may extend in a first direction orthogonal to the axis, and the second catch may extend in a second direction opposite the first direction and orthogonal to the axis. Additionally, in some embodiments, the plate body may include a convex outer surface connecting the upper surface and the lower surface.
The detailed description particularly refers to the following figures, in which:
While the concepts of the present disclosure are susceptible to various modifications and alternative forms, specific exemplary embodiments thereof have been shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that there is no intent to limit the concepts of the present disclosure to the particular forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.
Referring to
A door 22 is hinged to the front of the refrigerator cabinet 12 via an upper hinge assembly 24 and a lower hinge assembly 26, as described in greater detail below. The door 22 permits user access to the refrigerated compartment 20 such that food items may be placed in and retrieved from the refrigerator 10. When the door 22 is closed as shown in
As shown in
Referring now to
The mounting plate 46 extends outwardly from the flange 42 and the cabinet 12 when the hinge bracket 40 is secured to the cabinet 12. The mounting plate 46 has an upper surface 50, a lower surface 52 positioned opposite the upper surface 50, and an outer side wall 54 extending between the surfaces 50, 52. An opening 56 is defined in the upper surface 50 of the mounting plate 46, and an inner wall 58 extends downwardly from the opening 56 to define a bore 60 through the mounting plate 46. As shown in
Another opening 62 is defined in the upper surface 50 of the mounting plate 46 and is positioned between the bore 60 and the flange 42 of the hinge bracket 40. As shown in
The hinge assembly 26 of the refrigerator 10 also includes a hinge pin 80 configured to be coupled to the hinge bracket 40. The hinge pin 80 includes a base 82 and a circular flange 84 that extends outwardly from the base 82. The base 82 has an externally-threaded body 86 that extends downwardly from the circular flange 84. As shown in
As described above, the inner wall 58 of the hinge bracket 40 defines the bore 60 through the mounting plate 46. The inner wall 58 has a number of internal threads 88, which correspond to the external threads 90 of the hinge pin 80. When the base 82 of the hinge pin 80 is received in the bore 60 of the hinge bracket 40, the externally-threaded body 86 is engaged with the internally-threaded inner wall 58. The threaded engagement between the body 86 and the inner wall 58 permits the hinge pin 80 to be rotated about a vertically-extending longitudinal axis 92 while coupled to the hinge bracket 40.
As shown in
The hinge pin 80 of the hinge assembly 26 includes a cylindrical shaft 100 that extends upwardly from the circular flange 84. The shaft 100 is sized to be received in an opening 102 defined in a lower end 104 of the door 22. The shaft 100 defines a rotational axis 106 about which the door 22 may pivot between the open position and the closed position. In the illustrative embodiment, the rotational axis 106 is coaxial with the longitudinal axis 92, but it should be appreciated that in other embodiments the axes 106, 92 may be offset from one another.
In the illustrative embodiment, the hinge pin 80 is formed as a single monolithic component from a metallic material, such as, for example, steel. In other embodiments, the base 82, the circular flange 84, and the shaft 100 may be formed as separate components that are assembled. It should be appreciated that the configuration of one or more of those components of the hinge pin 80 may be modified in other embodiments. It should further be appreciated that in other embodiments one or more of the components may be made from a polymeric material, such as, for example, a rigid plastic.
As shown in
The cam plate 114 of the support 112 has a pair of curved walls 122 extending downwardly therefrom. Each wall 122 of the cam plate 114 includes a pair of angled cam surfaces 124, 126 and a substantially planar bottom surface 128 connecting the cam surfaces 124, 126. The walls 122 are arranged around the outer circumference of an opening 130 defined in the cam plate 114. As shown in FIG. 2, a cylindrical passageway 132 extends upwardly from the opening 130 through the cam plate 114 and the hollow rod 116 of the support 112. When door 22 is lowered onto the hinge pin 80, the shaft 100 of the hinge pin 80 is received in the cylindrical passageway 132 (see
As shown in
The platform 138 of the lower cam plate 134 has upper surface 142, a bottom surface 144 positioned opposite the upper surface 142, and an outer side wall 146 that connects the surfaces 142, 144. The outer side wall 146 of the platform 138 has a substantially planar surface 148 that extends upwardly from the bottom surface 144. The outer side wall 146 also has a convex surface 150 that bows outwardly from the upper surface 142 to meet the substantially planar surface 148.
As shown in
Returning to
The platform 138 of the lower cam plate 134 has a pair of curved walls 174 extending upwardly from the upper surface 142. As shown in
As described above, the main body 136 of the lower cam plate 134 includes a support arm 140 extends from the platform 138. The support arm 140 includes a substantially planar bottom surface 182 that is co-planar with the bottom surface 144 of the platform 138. The surfaces 144, 182 of the lower cam plate 134 are configured to contact the upper surface 50 of the hinge bracket 40 when the hinge assembly 26 is assembled.
Referring now to
The plug 184 of the lower cam plate 134 also includes a lower body 190 that is attached to the base 186. In the illustrative embodiment, the lower body 190 of the locking plug 184 includes a pair of outer beams 192, 194 extending downwardly from the base 186. A center beam 196, which also extends downwardly from the base 186, connects the outer beam 192 to the outer beam 194. As shown in
The outer beam 192 of the lower body 190 has an outer surface 200 that extends from an upper end 202 to a lower end 204. In the illustrative embodiment, the outer surface 200 is convex. It should be appreciated that in other embodiments the surface 200 may be flat or substantially planar. The other outer beam 194 also has an outer surface 206 that extends from the upper end 202 to the lower end 204 of the lower body 190. In the illustrative embodiment, the outer surface 206 is convex. It should be appreciated that in other embodiments the surface 206 may be flat or substantially planar.
The plug 184 also includes a longitudinal rib 208 extending outwardly from the surface 200 of the outer beam 192 and the surface 188 of the base 186. The rib 208 extends between the bottom surface 182 of the support arm 140 and the lower end 204 of the lower body 190. In the illustrative embodiment, the rib 208 has a semi-circular cross-section and includes a convex outer surface 210. It should be appreciated that in other embodiments the rib 208 may have a square, triangular, rectangular, or other cross-section.
As shown in
As shown in
The center beam 196 of the lower body 190 includes a side surface 222 and another side surface 224 that is positioned opposite the side surface 222. The outer beam 192 has an inner surface 226 extending outwardly from the side surface 222 of the center beam 196, and the outer beam 194 has an inner surface 228 that extends outwardly from the side surface 222. The surfaces 222, 226, 228 define a channel 230 in one side 232 of the plug 184. The channel 230 extends from the upper end 202 to the lower end 204 of the lower body 190.
Similarly, another channel 234 is defined in the plug 184 in an opposite side 234 thereof. The outer beam 192 has an inner surface 236 that extends outwardly from the side surface 224 of the center beam 196, and the outer beam 194 has an inner surface 238 that extends outwardly from the side surface 224. The surface 224, 236, 238 define the channel 234, which extends from the upper end 202 to the lower end 204 of the lower body 190.
The lower cam plate 134 of the hinge assembly 26 also includes a retention mechanism 240 to prevent inadvertent removal of the lower cam plate 134 from the hinge bracket 40. As shown in
The resilient tongue 244 of the retention mechanism 240 includes an arm 258 having an upper end 260 attached to the base 186 and a lower end 262 positioned adjacent to the lower end 204 of the lower body 190. As shown in
As shown in
The catches 252, 264 of the tongues 242, 244, respectively, extend orthogonally to the axis 220 defined by the center beam 196 of the plug 184 and in opposite directions. As shown in
To assemble the hinge assembly 26, the hinge pin 80 is aligned with the opening 56 defined in the mounting plate 46 of the hinge bracket 40. The base 82 of the hinge pin 80 is advanced into the bore 60 of the mounting plate 46, and the hinge pin 80 is rotated about the axis 92 to engage the external threads 90 of the base 82 with the internal threads 88 of the mounting plate 46. As shown in
To attach the lower cam plate 134, the plug 184 of the lower cam plate 134 is aligned with the slot 76 defined in the mounting plate 46 of the hinge bracket 40, as shown in
If the cam plate 134 is moved upward, the upper surface 254 of the catch 252 may be advanced into contact with the section 270 of the lower surface 52 of the mounting plate 46. Similarly, the upper surface 266 of the other catch 264 may be advanced into contact with the surface section 272. The engagement between the catches 252, 264 and the mounting plate 46 retains the plug 184 in the slot 76, thereby preventing the inadvertent removal of the lower cam plate 134 from the hinge bracket 40.
When the hinge pin 80 and the cam plate 134 are attached to the hinge bracket 40, the door 22 may be lowered onto the hinge pin 80. The shaft 100 of the hinge pin 80 is aligned with the opening 130 of the upper cam plate 114, and the door 22 is lowered such that the shaft 100 is received in the cylindrical passageway 132. As shown in
The user may then adjust the vertical height of the door 22 relative to the cabinet 12 and the door 32. To do so, the user may attach a socket or other tool to the lower end 94 of the hinge pin 80 to rotate the hinge pin 80 about the axis 92. As shown in
The assembly may continue to move upward until the upper surfaces 254, 266 of the catches 252, 264 are advanced into contact with the lower surface 52 of the mounting plate 46, as shown in
As described above, the door 22 is pivoted about an axis 106 as the door 22 is moved between the open and the closed position. When the door 22 is in the closed position, the cam surfaces 124, 126 of the walls 122 of the upper cam plate 114 confront the corresponding cam surfaces 176, 178 of the walls 174 of the lower cam plate 134, as shown in
The engagement between the rib 208 and the wall section 68 of the inner wall 64 of the hinge bracket 40 prevents the lower cam plate 134 from pivoting with the door 22 and the upper cam plate 114. As a result, the walls 122 of the upper cam plate 114 slide upwardly along the cam surfaces 176, 178 of the lower cam plate 134 as the door 22 is pivoted about the axis 106, thereby lifting the door 22 as the door 22 is opened.
When the user closes the door 22, the walls 122 of the upper cam plate 114 advance along the top surface 180 of the lower cam plate 134 and then downward along the cam surfaces 176, 178 of the lower cam plate 134 such that the door 22 is lowered as the door 22 is moved to the closed position.
There are a plurality of advantages of the present disclosure arising from the various features of the method, apparatus, and system described herein. It will be noted that alternative embodiments of the method, apparatus, and system of the present disclosure may not include all of the features described yet still benefit from at least some of the advantages of such features. Those of ordinary skill in the art may readily devise their own implementations of the method, apparatus, and system that incorporate one or more of the features of the present invention and fall within the spirit and scope of the present disclosure as defined by the appended claims.