Hinge and refrigeration device having the same
By designing a hinge structure that combines a slider and a groove, the problem of interference between the door and the cabinet wall in an embedded refrigerator was solved, enabling the door to open and close stably in various application scenarios, thus enhancing the aesthetics and functionality of the refrigerator.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- QINDAO HAIER REFRIGERATOR CO LTD
- Filing Date
- 2022-01-05
- Publication Date
- 2026-07-07
AI Technical Summary
In embedded applications, existing refrigerator hinges can easily interfere with cabinet walls or doors when the door is opened, affecting aesthetics and potentially damaging the door.
A hinge structure was designed, including a fixed seat, a movable seat, and a linkage component. Through the cooperation of the slider and the slide groove, the movable seat can rotate and move simultaneously when the door is opened, thereby controlling the movement trajectory of the door and avoiding interference.
The door's versatility has been enhanced, enabling it to adapt to various application scenarios, especially built-in refrigerators, preventing the door from colliding with the cabinet walls and maintaining an aesthetically pleasing appearance.
Smart Images

Figure CN116411754B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of home appliance technology, and more particularly to a hinge and a refrigeration device having the hinge. Background Technology
[0002] With societal progress and improved living standards, the placement and arrangement of refrigerators in homes are increasingly valued by ordinary users. Given current home décor trends, some families seek a unified style, requiring the refrigerator to be placed within cabinets, creating a so-called built-in refrigerator unit. Typically, when the door opens, it rotates around the hinge axis. The side of the door that hinges to the refrigerator body often protrudes from the cabinet's side wall. While this isn't a problem when placed outside the cabinet due to ample space, it interferes with the cabinet walls or doors when placed inside. This not only affects the opening range of the refrigerator door but also damages the door's surface, affecting its aesthetics. In short, current refrigerators are ill-suited for this built-in application scenario.
[0003] In view of this, it is necessary to improve the existing hinges and the refrigeration devices with such hinges in order to solve the above problems. Summary of the Invention
[0004] The purpose of this invention is to provide a hinge and a refrigeration device having the hinge.
[0005] To achieve one of the above-mentioned objectives, the present invention provides a hinge for connecting a door to a housing; the hinge includes:
[0006] A fixed base is fixed to the housing, and the fixed base has a first sliding groove and a slider that is slidably connected to the first sliding groove.
[0007] A movable seat is connected to the door body, and one end of the movable seat is connected to a hinge shaft;
[0008] A linkage component is provided between the slider and the movable seat. When the movable seat rotates open about the hinge axis away from the fixed seat, the linkage component drives the slider to move along the first slide groove, causing the movable seat to move a preset distance in the same direction.
[0009] To achieve the above-mentioned objectives, the present invention also provides a hinge for connecting a door to a housing; the hinge includes:
[0010] A fixed base is fixed to the housing, and the fixed base has a first sliding groove and a slider that is slidably connected to the first sliding groove.
[0011] A movable seat is connected to the door body, and one end of the movable seat is connected to a hinge shaft;
[0012] A linkage component is disposed between the slider and the movable seat. When the movable seat rotates in place by a preset angle about the hinge axis away from the fixed seat, and then continues to rotate and open away from the fixed seat, the linkage component drives the slider to move along the first slide groove, thereby causing the movable seat to move a preset distance in the same direction.
[0013] As a further improvement of the present invention, the movable seat is provided with a clearance groove, and the linkage component has a first rotating shaft that cooperates with the clearance groove. The clearance groove is an arc-shaped groove with the hinge axis as the center. When the movable seat rotates about the hinge axis away from the fixed seat, the first rotating shaft cooperates with the clearance groove to make the movable seat rotate in place by a preset angle.
[0014] As a further improvement of the present invention, the first slide extends along the length direction of the fixed seat, and the first slide has an outer end close to the hinge axis and an inner end away from the hinge axis. When the movable seat rotates open about the hinge axis away from the fixed seat, the linkage component drives the slider to move from the outer end to the inner end, thereby driving the movable seat to move in the same direction.
[0015] As a further improvement of the present invention, the movable seat is provided with a second slide groove extending along the length direction of the movable seat, and the linkage component has a first rotating shaft that cooperates with the second slide groove. When the movable seat is rotated open in a direction away from the fixed seat so that the linkage component drives the slider to move along the first slide groove, the first rotating shaft moves to one end of the second slide groove near the hinge shaft.
[0016] As a further improvement of the present invention, the length of the second groove is not less than the length of the first groove.
[0017] As a further improvement of the present invention, after the linkage component drives the slider to move along the first slide groove and drives the movable seat to move a preset distance in the same direction, the movable seat can rotate in place around the hinge axis.
[0018] As a further improvement of the present invention, the movable seat includes a fixed plate fixed to the door body and a linkage plate rotatably connected to the fixed plate through the hinge shaft. The linkage plate is movably connected to the linkage assembly. The fixed plate has a linkage state that is fixed relative to the linkage plate and a disengaged state that can be detached from the linkage plate.
[0019] As a further improvement of the present invention, the linkage component includes a telescopic rod assembly, one end of which is rotatably connected to the fixed seat and the other end is movably connected to the movable seat. The telescopic rod assembly has a non-extendable first state and a extendable second state. When the telescopic rod assembly is in the first state, during the rotation of the movable seat around the hinge axis, the linkage component drives the movable seat to move synchronously with the slider. When the telescopic rod assembly is in the second state, the movable seat can rotate in place around the hinge axis.
[0020] To achieve the above-mentioned objectives, the present invention also provides a refrigeration device, including a housing, a door, and the aforementioned hinge.
[0021] Compared with the prior art, the beneficial effects of the present invention are as follows: the movable seat fixed to the door body in the hinge of the present invention can rotate and move with the slider, thereby controlling the movement trajectory of the door body, enhancing the versatility of the door body, and enabling the door body to adapt to various application scenarios, such as the application scenario of embedded refrigerators. Attached Figure Description
[0022] Figure 1 This is a schematic diagram of the hinge structure in the first embodiment of the present invention;
[0023] Figure 2 yes Figure 1 Enlarged view of point A in the middle;
[0024] Figure 3 yes Figure 1 A schematic diagram of the structure of the movable seat in the hinge after it is opened (the movable seat and the slider are in a linked state);
[0025] Figure 4 yes Figure 1 A schematic diagram of the structure of the movable seat in the hinge after it is opened (the movable seat and the slider are in a non-linked state);
[0026] Figure 5 This is a schematic diagram of the hinge structure in the second embodiment of the present invention;
[0027] Figure 6 This is a schematic diagram of the hinge structure in the third embodiment of the present invention;
[0028] Figure 7 yes Figure 6 Enlarged view of point B in the middle;
[0029] Figure 8 yes Figure 6 A schematic diagram of the linkage components in the folded state;
[0030] Figure 9 yes Figure 6Schematic diagram of the structure after the movable seat in [it] is opened (the fixed plate and the linkage plate in the movable seat are in a linked state);
[0031] Figure 10 is Figure 6 Schematic diagram of the structure after the movable seat in [it] is opened (the fixed plate and the linkage plate in the movable seat are in a disengaged state);
[0032] Figure 11 Schematic diagram of the structure of the hinge in the fourth embodiment of the present invention (the linkage component is in a folded state);
[0033] Figure 12 is Figure 11 after the fixed plate in the hinge in [it] rotates in place around the hinge axis by a preset angle;
[0034] Figure 13 is Figure 11 Schematic diagram of the structure after the movable seat in [it] is opened (the fixed plate and the linkage plate in the movable seat are in a linked state);
[0035] Figure 14 is Figure 11 Schematic diagram of the structure after the movable seat in [it] is opened (the fixed plate and the linkage plate in the movable seat are in a disengaged state);
[0036] Figure 15 Schematic diagram of the structure of the refrigeration device in the present invention. Specific embodiments
[0037] The following will combine the attached Figure 1-15 The specific embodiments shown will be used to describe the present invention in detail. However, these embodiments do not limit the present invention, and any structural, method, or functional transformation made by those of ordinary skill in the art based on these embodiments is included within the protection scope of the present invention.
[0038] The terms used herein to represent relative spatial positions are for the purpose of facilitating the description of the relationship between one unit or feature and another unit or feature as shown in the drawings. The terms of relative spatial positions may be intended to include different orientations of the device in use or operation other than the orientation shown in the figures. For example, if the device in the figure is flipped, the unit described as being "below" or "beneath" other units or features will be located "above" other units or features. Thus, the exemplary term "below" can encompass both the upper and lower orientations. The device can be oriented in other ways (rotated 90 degrees or other orientations), and the spatially related descriptive terms used herein can be interpreted accordingly.
[0039] Refer Figures 1-4As shown, the hinge 10 in the first embodiment of the present invention is used to connect the door to the cabinet. In this embodiment, the hinge 10 is applied to a vertical refrigerator and the refrigerator door is a left-right opening door for specific explanation.
[0040] Of course, it should be emphasized that the hinge 10 of this embodiment is not only applicable to refrigerators, but also to other scenarios, such as cabinets, wine cabinets, wardrobes, etc. This invention uses the application of the hinge 10 to a refrigerator as an example for illustration, but it is not limited thereto.
[0041] The hinge 10 includes a fixed base 1 for fixing to the housing, a movable base 2 for fixing to the door, and a linkage assembly 3. The fixed base 1 has a first sliding groove 11 and a slider 12 slidably connected to the first sliding groove 11. The movable base 2 has a hinge axis 21, and the movable base 2 can rotate around the hinge axis 21, so that the door fixed to the movable base 2 can rotate around the hinge axis 21 to open or close the housing. The linkage assembly 3 is disposed between the slider 12 and the movable base 2 to link the movable base 2 and the slider 12.
[0042] Specifically, the movable seat 2 has a linked state in which it rotates around the hinge axis 21 and moves synchronously with the slider 12, and a non-linked state in which it rotates only around the hinge axis 21. When the movable seat 2 and the slider 12 are in the linked state, when the movable seat 2 rotates around the hinge axis 21 to open, the linkage component 3 drives the movable seat 2 to move a preset distance with the slider 12; when the movable seat 2 and the slider 12 are in the non-linked state, the movable seat 2 can rotate freely in place around the hinge axis 21, and can control the movement trajectory of the door.
[0043] It is understood that the direction and preset distance of movement of the movable seat 2 driven by the linkage component 3 are related to the direction and distance of movement of the slider 12. The extension direction of the first slide groove 11, the movement direction of the slider 12, and the length of the first slide groove 11 can be designed according to specific needs. For example, to prevent the door from colliding with the wall / cabinet on the opening side when it is opened, the extension direction of the first slide groove 11 can be designed to extend in a direction perpendicular to the wall / cabinet on the opening side (extending in the length direction of the fixed seat 1), and the movement direction of the slider 12 when the door is opened is to move along the first slide groove 11 in a direction away from the wall / cabinet on the opening side. If the door is to move outwards in a direction away from the opening side to increase the opening degree, the extension direction of the first slide groove 11 can be designed to extend in a direction perpendicular to the wall / cabinet on the opening side (extending in the length direction of the fixed seat 1), and the movement direction of the slider 12 when the door is opened is to move along the first slide groove 11 in a direction towards the wall / cabinet on the opening side.
[0044] In this embodiment, the first slide groove 11 extends along the length of the fixed base 1. The end of the first slide groove 11 closest to the hinge axis 21 is defined as the outer end, and the end furthest from the hinge axis 21 is defined as the inner end. When the movable base 2 and the slider 12 are in a linked state, and the movable base 2 rotates open around the hinge axis 21 in a direction away from the fixed base 1, the slider 12 moves along the first slide groove 11 from the outer end to the inner end, causing the door to move inward. That is, the door moves inward a preset distance while rotating and opening, preventing collisions between the door and the wall or cabinet on the open side. Of course, this is not a limitation. In other embodiments, when the movable base 2 and the slider 12 are in a linked state, and the movable base 2 rotates open around the hinge axis 21 in a direction away from the fixed base 1, the slider 12 moves along the first slide groove 11 from the inner end to the outer end, causing the door to move outward. That is, the door moves outward a preset distance while rotating and opening, increasing the opening angle of the door and making it easier for the user to view the items inside the refrigerator.
[0045] Specifically, the preset distance by which the linkage component 3 moves the door can be adjusted by adjusting the length of the first slide groove 11.
[0046] It should be noted that "outer" refers to the outside of the refrigerator, while "inner" is a direction defined relative to "outer".
[0047] It is understood that when the hinge 10 is applied to a refrigerator with left and right doors, the length direction of the aforementioned fixing base 1 is the left-right direction, and the aforementioned outer end refers to the end of the first slide groove 11 corresponding to the opening side of the door. When the hinge 10 is applied to a refrigerator with top and bottom doors, the length direction of the aforementioned fixing base 1 is the top-bottom direction, and the aforementioned outer end refers to the end of the first slide groove 11 corresponding to the opening side of the door.
[0048] Specifically, the fixing base 1 includes a first plate 13 for fixing to the box body, a connecting plate 14 vertically disposed on the first plate 13, and the first sliding groove 11 disposed on the connecting plate 14.
[0049] The first plate 13 is fixed to the side of the box body facing the door so that the connecting plate 14 protrudes towards the door body.
[0050] It is understood that the position of the first slide groove 11 is set according to the relative positional relationship between the connecting plate 14 and the door body; that is, the first slide groove 11 is set on the side of the first plate 13 corresponding to the door body. For example, when the hinge 10 is installed at the bottom of the upright refrigerator and the door body is a left-right opening door, the door body is located above the hinge 10, therefore, the first slide groove 11 is set on the upper surface of the connecting plate 14.
[0051] Furthermore, the linkage component 3 has a folded state and an open state. When the movable seat 2 and the slider 12 are in the linkage state, during the process of the movable seat 2 rotating and opening around the hinge axis 21 in a direction away from the fixed seat 1, the linkage component 3 switches from the folded state to the open state, driving the slider 12 to move along the slide groove, and at the same time driving the movable seat 2 to move with the slider 12.
[0052] In this embodiment, when the linkage component 3 is in the folded state, the door is in the closed state. At this time, the movable seat 2 and the slider 12 are in a linkage state. When the door is opened, the movable seat 2 rotates around the hinge axis 21 in a direction away from the fixed seat 1. At the same time, the linkage component 3 switches from the folded state to the open state. That is, when the door is opened, the door rotates around the hinge axis 21 and moves inward synchronously with the slider 12 to prevent the door from colliding with the wall / cabinet on the open side during the opening process.
[0053] In one specific embodiment, the linkage component 3 includes a first link 31, a second link 32, and a third link 33. The first link 31, the second link 32, the third link 33, and the movable seat 2 form a four-bar linkage structure to realize the linkage between the slider 12 and the movable seat 2.
[0054] Specifically, one end of the first connecting rod 31 is rotatably connected to the hinge shaft 21, and the other end is rotatably connected to the slider 12. One end of the second connecting rod 32 is rotatably connected to the fixed seat 1 at the end corresponding to the inner end, and the other end is movably connected to the movable seat 2. One end of the third connecting rod 33 is rotatably connected to the slider 12, and the other end is rotatably connected to the second connecting rod 32. When the linkage assembly 3 is in the folded state, the first connecting rod 31, the second connecting rod 32, the third connecting rod 33, and the movable seat 2 are stacked.
[0055] During the opening process, when the door body drives the movable seat 2 to rotate around the hinge axis 21, the linkage component 3 drives the slider 12 to move inward, causing the movable seat 2 to move inward, so that the door body moves inward to avoid the door body colliding with the wall or cabinet on the open side when the door is opened.
[0056] In one specific embodiment, the first connecting rod 31 and the third connecting rod 33 are rotatably connected to the slider 12 via the same pivot. Of course, this is not a limitation.
[0057] In one specific embodiment, the movable seat 2 is provided with a second slide groove 22 extending along its length. The second connecting rod 32 has a first rotating shaft 321 that cooperates with the second slide groove 22. The cooperation between the first rotating shaft 321 and the second slide groove 22 allows the second connecting rod 32 to be movably connected to the movable seat 2. During the door opening process, when the movable seat 2 and the slider 12 are in a linked state, as the movable seat 2 continues to rotate around the hinge axis 21 to further open the door, the linkage component 3 drives the slider 12 to move inward. At the same time, the first rotating shaft 321 moves along the second slide groove 22 towards the end of the second slide groove 22 closer to the hinge axis 21. This reduces the rotation angle of the door during the inward movement of the door driven by the slider 12, enhancing the stability of the door movement. Of course, this is not a limitation. In other embodiments, the first rotating shaft 321 may also be configured to be rotatably connected only to the movable seat 2.
[0058] Furthermore, in this embodiment, the second connecting rod 32 includes a connecting rod 322 rotatably connected to the fixed base 1, a telescopic rod 323 slidably connected to the connecting rod 322 along the length direction of the connecting rod 322, and the third connecting rod 33 is rotatably connected to the connecting rod 322.
[0059] The telescopic rod 323 has a non-extendable first state and a telescopic second state. When the telescopic rod 323 is in the first state, the movable seat 2 and the slider 12 can be in a linked state. When the telescopic rod 323 is in the second state, the movable seat 2 and the slider 12 are in a non-linked state, that is, the movable seat 2 can rotate in place around the hinge axis 21.
[0060] Specifically, in this embodiment, after the door is opened and the slider 12 moves to the inner end of the first slide groove 11, the telescopic rod 323 switches from the first state to the second state. That is, during the rotation of the movable seat 2 around the hinge axis 21 in a direction away from the fixed seat 1, the second connecting rod 32 is first in the first state and then in the second state. After the door body moves inward, the telescopic rod 323 switches from the first state to the second state, and the movable seat 2 can rotate freely around the hinge axis 21 in place. That is, the door body can rotate freely around the hinge axis 21 in place to further open the door body, making it easier for the user to retrieve items.
[0061] It is understood that in the embodiment where the second link 32 includes the telescopic rod 323, the second slide groove 22 provided on the movable seat 2 can increase the opening of the door, making it easier for the user to retrieve items.
[0062] In one specific embodiment, one of the telescopic rod 323 and the third connecting rod 33 is provided with a limiting groove 3231, and the other is provided with a limiting block 331 that cooperates with the limiting groove 3231. When the limiting block 331 is located in the limiting groove 3231, the telescopic rod 323 is in a first state. After the limiting block 331 disengages from the limiting groove 3231, the telescopic rod 323 is in a second state.
[0063] Specifically, the limiting groove 3231 is an arc-shaped groove centered on the rotation center between the third link 33 and the second link 32. When the linkage assembly 3 switches from the folded state to the open state, the limiting block 331 moves relative to the limiting groove 3231. After the slider 12 moves to the inner end of the first slide groove 11, the limiting block 331 disengages from the limiting groove 3231, so that the telescopic rod 323 is in the second state. The movable seat 2 can rotate freely around the hinge axis 21 in place. That is, the door 30 can rotate freely around the hinge axis 21 in place to further open the door 30, making it easier for the user to take out items.
[0064] It is understandable that the cooperation between the limiting groove 3231 and the limiting block 331 can, on the one hand, enable the telescopic rod 323 to be in the first state, so that the movable seat 2 and the slider 12 can be in a linked state; on the other hand, it can enhance the stability of the relative movement between the first rotating shaft 321 and the second sliding groove 22, and enhance the stability of the hinge 10.
[0065] Furthermore, the fixed base 1 is also provided with a protrusion 15, which is located on the same side of the connecting plate 14 as the first sliding groove 11. After the linkage component 3 drives the slider 12 to move to the inner end, the first connecting rod 31 abuts against the protrusion 15 to restrict the rotation of the first connecting rod 31, thereby enhancing the stability of the door body 30 to rotate freely in place around the hinge axis 21.
[0066] Furthermore, the hinge 10 also includes a docking post 5 disposed on the movable seat 2 for fixing the movable seat 2 relative to the door body, so as to realize docking with the corresponding structure on the door body and fix the movable seat 2 to the door body.
[0067] Further, please refer to Figure 15 As shown, the present invention also provides a refrigeration device 100, the refrigeration device 100 including a housing 20, a door 30 for opening and closing the housing 20, and a hinge 10 for connecting the housing 20 and the door 30.
[0068] The hinge 10 is the hinge 10 in the first embodiment of the present invention described above, and will not be described again here.
[0069] In this embodiment, the refrigeration device 100 is a vertical refrigerator with left and right doors. Of course, it should be emphasized that the refrigeration device 100 can also be a vertical refrigerator with top and bottom doors or a horizontal freezer, etc.
[0070] The opening and closing process of the refrigeration device 100 with the hinge 10 is described below:
[0071] When the door 30, which is in a closed state, is opened, the door 30 rotates around the hinge axis 21 in a direction away from the box 20, and at the same time moves inward a preset distance with the slider 12 under the action of the linkage component 3;
[0072] After the door body 30 has moved inward, the door body 30 can rotate freely in place around the hinge axis 21;
[0073] When the door 30 is closed from the open state, the door 30 first rotates around the hinge axis 21 in place toward the direction of the box 20 until the movable seat 2 and the slider 12 are in a linked state;
[0074] After the door is closed until the movable seat 2 and the slider 12 are in a linked state, the door 30 rotates around the hinge axis 21 in the direction closer to the box 20. At the same time, under the action of the linkage component 3, the door 30 moves outward a preset distance with the slider 12 and then the door 30 is in a closed state.
[0075] It is understood that the preset distance for the door body 30 to move inward and the preset distance for it to move outward can both be preset by adjusting the length of the first slide groove 11.
[0076] The completion of the inward movement of the aforementioned door body 30 means that the slider 12 moves to the inner end and the telescopic rod 323 is in the second state.
[0077] The aforementioned closing of the door to the point where the movable seat 2 and the slider 12 are in a linked state means that when the door is closed to the point where the telescopic rod 323 switches from the second state to the first state, the movable seat 2 and the slider 12 are in a linked state.
[0078] Please refer to Figure 5 As shown, the hinge 10a is shown in the second embodiment of the present invention. For ease of explanation, the structures in the second embodiment that are similar or the same as those in the first embodiment are given the same or similar numbers, and the structures in the second embodiment that are the same as those in the first embodiment will not be described again here.
[0079] The difference between the hinge 10a in the second embodiment of the present invention and the hinge 10 in the first embodiment is that the movable seat 2a is further provided with a first clearance groove 23. The first clearance groove 23 is an arc-shaped groove with the hinge shaft 21 as the center. The first rotating shaft 321 is movably connected in the first clearance groove 23. Through the cooperation between the first rotating shaft 321 and the first clearance groove 23, the movable seat 2a can rotate in place only around the hinge shaft 21, that is, it is in a non-linkage state.
[0080] In one specific embodiment, during the rotation of the movable seat 2a around the hinge axis 21 in a direction away from the fixed seat 1, the movable seat 2a is first in the non-linkage state and then in the linkage state. That is, the first rotating shaft 321 first cooperates with the first clearance groove 23 to make the movable seat 2a rotate only around the hinge axis 21 in place, and then the movable seat 2a switches to the linkage state. Thus, when opening the door, the door body 30 can first rotate in place around the hinge axis 21 in a direction away from the box body 20 by a preset angle, and then rotate open and move inward under the action of the linkage component 3. In the final stage of closing the door, the door body 30 can first rotate in place around the hinge axis 21 in a direction closer to the box body 20 by a preset angle. This is suitable for door bodies 30 with a flip beam and makes it more convenient to open and close the door body 30.
[0081] It is understandable that the aforementioned preset angle is determined by the length of the first clearance groove 23.
[0082] In an embodiment where the second slide groove 22 is provided on the movable seat 2a, the first clearance groove 23 is located at the end of the second slide groove 22 away from the hinge shaft 21, and the first clearance groove 23 is connected to the second slide groove 22.
[0083] The hinge 10a in the second embodiment of the present invention is the same as the hinge 10 in the first embodiment except for the differences mentioned above, and will not be described again here.
[0084] Further, please refer to Figure 15 As shown, the present invention also provides a refrigeration device 100, the refrigeration device 100 including a housing 20, a door 30 for opening and closing the housing 20, and a hinge 10a for connecting the housing 20 and the door 30.
[0085] The hinge 10a is the hinge 10a in the second embodiment of the present invention described above, and will not be described again here.
[0086] In this embodiment, the refrigeration device 100 is a vertical refrigerator with left and right doors. Of course, it should be emphasized that the refrigeration device 100 can also be a vertical refrigerator with top and bottom doors or a horizontal freezer, etc.
[0087] The opening and closing process of the refrigeration device 100 with the hinge 10a is described below:
[0088] When the door 30, which is in a closed state, is opened, the door 30 first rotates in place around the hinge axis 21 by a preset angle;
[0089] After the door 30 rotates to a preset angle, the movable seat 2a is in a linked state. The door 30 continues to rotate around the hinge axis 21 in a direction away from the box 20, while the slider 12 moves inward a preset distance under the action of the linkage component 3.
[0090] After the door body 30 has moved inward, the door body 30 can rotate freely in place around the hinge axis 21;
[0091] When the door 30 is closed from the open state, the door 30 first rotates around the hinge axis 21 in place toward the direction of the box 20 until the movable seat 2a is in the linkage state;
[0092] After the door is closed until the movable seat 2a is in the linkage state, the door body 30 rotates around the hinge axis 21 in the direction closer to the box body 20. At the same time, under the action of the linkage component 3, it moves outward a preset distance with the slider 12 until the movable seat 2a is in the non-linkage state again.
[0093] After the movable seat 2a is in a non-linkage state again, the door 30 rotates in place around the hinge axis 21 toward the box 20 by a preset angle and then the door 30 is in a closed state.
[0094] It is understandable that during the opening process, the door body 30 mentioned above first rotates around the hinge axis 21 in place by a preset angle, that is, the door body 30 rotates around the hinge axis 21 in place until the first rotating shaft 321 enters the second sliding groove 22 from the first clearance groove 23.
[0095] The preset distances for the inward and outward movement of the door 30 can be preset by adjusting the length of the first slide groove 11.
[0096] The completion of the inward movement of the aforementioned door body 30 means that the slider 12 moves to the inner end and the telescopic rod 323 is in the second state.
[0097] The aforementioned closing of the door to the movable seat 2a being in a linked state means that closing the door to the telescopic rod 323 switching from the second state to the first state.
[0098] The aforementioned movable seat 2a is again in a non-linkage state, that is, during the closing process, the first rotating shaft 321 enters the first clearance groove 23 from the second sliding groove 22.
[0099] Please refer to Figures 6-10 As shown, the hinge 10b is shown in the third embodiment of the present invention. For ease of explanation, the structures in the third embodiment that are similar or the same as those in the first embodiment are numbered the same or similarly, and the structures in the third embodiment that are the same as those in the first embodiment will not be repeated here.
[0100] The difference between the third embodiment and the first embodiment is that the movable seat 2b includes a fixed plate 24 fixed to the door body 30 and a linkage plate 25 rotatably connected to the fixed plate 24 through the hinge shaft 21. The second connecting rod 32b is movably connected to the linkage plate 25. The fixed plate 24 has a linkage state that is relatively fixed to the linkage plate 25 and a disengaged state that can be separated from the linkage plate 25. When the fixed plate 24 is in the linkage state, the linkage component 3 can drive the fixed plate 24 and the slider 12 to move synchronously. When the fixed plate 24 is in the disengaged state, the fixed plate 24 can rotate around the hinge shaft 21 in place, so as to drive the door body 30 to rotate around the hinge shaft 21 in place.
[0101] In this embodiment, the second link 32b is an integral link, that is, the second link 32b is a non-retractable link.
[0102] It should be noted that, in this embodiment, the limiting groove and limiting block that cooperate between the second connecting rod 32b and the third connecting rod 33 can enhance the stability of the first rotating shaft 321 moving along the second sliding groove 22 and enhance the stability of the hinge 10b.
[0103] It is understood that in this embodiment, the linkage plate 25 and the slider 12 are always in a linkage state. The fixing plate 24 and the linkage plate 25 are switched between the linkage state and the disengagement state, thereby controlling the switching between the linkage state and the non-linkage state of the fixing plate 24 and the slider 12.
[0104] In this embodiment of hinge 10b, where the movable seat 2b has the second slide groove 22, the second slide groove 22 extends through the fixed plate 24. The first rotating shaft 321 in the second connecting rod 32b is movably connected within the second slide groove 22, so that the second connecting rod 32b is movably connected to the linkage plate 25. During the movement of the linkage plate 25 around the hinge axis 21 away from the fixed seat 1, while the linkage assembly 3 drives the slider 12 to move inward, the first rotating shaft 321 moves along the second slide groove 22 towards the end of the second slide groove 22 closer to the hinge axis 21. This reduces the rotation angle of the door 30 during the inward movement of the slider 12, enhancing the stability of the opening process. However, this is not a limitation; in other embodiments, the first rotating shaft 321 may also be configured to be rotatably connected only to the linkage plate 25.
[0105] Furthermore, the fixing plate 24 is provided with a third sliding groove 241 extending along its length direction. When the fixing plate 24 and the linkage plate 25 are in a linked state, the third sliding groove 241 is aligned with the second sliding groove 22, and the first rotating shaft 321 cooperates with both the second sliding groove 22 and the third sliding groove 241. When the first rotating shaft 321 disengages from the third sliding groove 241, the fixing plate 24 and the linkage plate 25 are in a disengaged state.
[0106] That is, the fixed plate 24 can switch between the linked state and the disengaged state through the cooperation between the first rotating shaft 321 and the third sliding groove 241. The structure is simple, easy to set up, and low in cost.
[0107] It is understandable that during the door opening process, when the fixed plate 24 and the linkage plate 25 are in a linked state, as the movable seat 2b continues to rotate around the hinge axis 21 to further open the door 30, the linkage component 3 drives the slider 12 to move inward, while the first rotating shaft 321 moves along the second slide groove 22 and the third slide groove 241 towards the end of the second slide groove 22 and the third slide groove 241 closer to the hinge axis 21.
[0108] Furthermore, the fixing plate 24 is provided with a notch 242 communicating with the third slide groove 241 on the side facing the linkage plate 25. The notch 242 is used to allow the first rotating shaft 321 to disengage from or enter the third slide groove 241. When the first rotating shaft 321 moves along the third slide groove 241 to disengage from the third slide groove 241 through the notch 242, the fixing plate 24 and the linkage plate 25 are in a disengaged state. The fixing plate 24 can rotate in place around the hinge axis 21, that is, the door body 30 can rotate in place around the hinge axis 21.
[0109] Specifically, when the linkage component 3 drives the slider 12 to move along the preset direction to one end of the first slide groove 11, the first rotating shaft 321 is located at the notch 242. That is, in this embodiment, when the linkage component 3 drives the slider 12 to move along the first slide groove 11 to the inner end, the first rotating shaft 321 is located at the notch 242. That is, after the door 30 completes the inward movement during the opening process, the first rotating shaft 321 is located at the notch 242. At this time, if the door continues to open, the first rotating shaft 321 will disengage from the third slide groove 241 from the notch 242, causing the fixing plate 24 to switch to the disengaged state. Thus, the door 30 can enter a state of free rotation around the hinge axis 21, which is convenient for the user to retrieve items.
[0110] Furthermore, the fixed plate 24 has an inclined surface 243 on the side facing the linkage plate 25, which extends from the end of the third slide groove 241 away from the hinge shaft 21 toward the hinge shaft 21 and in a direction away from the linkage plate 25. The inclined surface 243 extends to the position of the notch 242, so that the first rotating shaft 321 can enter and exit the third slide groove 241 through the notch 242.
[0111] Furthermore, an alignment structure 4 is provided between the fixed plate 24 and the linkage plate 25. When the fixed plate 24 rotates around the hinge axis 21 toward the fixed seat 1, the alignment structure 4 is used to align the relative positions between the linkage plate 25 and the fixed plate 24, thereby enhancing the stability of the hinge 10b operation.
[0112] In one specific embodiment, the alignment structure 4 includes an alignment post 41 disposed on one of the fixed plate 24 and the linkage plate 25, and an alignment groove 42 disposed on the other. The alignment groove 42 has an inlet and outlet for the alignment post 41 to enter and exit. In this embodiment, after the fixed plate 24 rotates in place toward the fixed seat 1 about the hinge axis 21 until the alignment post 41 abuts against the groove wall of the alignment groove 42, the second sliding groove 22 and the third sliding groove 241 are aligned.
[0113] The hinge 10b in the third embodiment of the present invention is the same as the hinge 10b in the first embodiment except for the differences mentioned above, and will not be described again here.
[0114] Further, please refer to Figure 15 As shown, the present invention also provides a refrigeration device 100, the refrigeration device 100 including a housing 20, a door 30 for opening and closing the housing 20, and a hinge 10b for connecting the housing 20 and the door 30.
[0115] The hinge 10b is the hinge 10b in the third embodiment of the present invention described above, and will not be described again here.
[0116] In this embodiment, the refrigeration device 100 is a vertical refrigerator with left and right doors. Of course, it should be emphasized that the refrigeration device 100 can also be a vertical refrigerator with top and bottom doors or a horizontal freezer, etc.
[0117] The opening and closing process of the refrigeration unit 100 with the hinge 10b is described below:
[0118] In the first stage of opening the door 30 which is in the closed state, the door 30 rotates around the hinge axis 21 in a direction away from the box 20, while moving inward a preset distance with the slider 12 under the action of the linkage component 3;
[0119] After the door body 30 has moved inward, the fixing plate 24 is in a disengaged state, and the door body 30 can rotate freely around the hinge axis 21 in place;
[0120] When the door 30 is closed from the open state, the door 30 first rotates around the hinge axis 21 in place toward the direction of the box 20 until the fixed plate 24 is in a linked state;
[0121] After the door is closed until the fixed plate 24 and the linkage plate 25 are in a linked state, the door body 30 rotates around the hinge axis 21 in the direction closer to the box body 20. At the same time, under the action of the linkage component 3, the door body 30 moves outward by a preset distance with the slider 12 and then the door body 30 is in a closed state.
[0122] It is understood that the preset distance for the door body 30 to move inward and the preset distance for it to move outward can both be preset by adjusting the length of the first slide groove 11.
[0123] When the door body 30 moves inward, it means that the slider 12 moves to the inner end. At this time, the first rotating shaft 321 is located at the notch 242, which makes it easier for the first rotating shaft 321 to disengage from the third sliding groove 241 through the notch 242.
[0124] The aforementioned closing of the door until the fixed plate 24 and the linkage plate 25 are in a linked state means that the door is closed until the first rotating shaft 321 enters the third sliding groove 241 through the notch 242. It can be understood that after the alignment post 41 abuts against the groove wall of the alignment groove 42, the third sliding groove 241 aligns with the second sliding groove 22, facilitating the entry of the first rotating shaft 321 into the third sliding groove 241.
[0125] Please refer to Figures 11-14 As shown, the hinge 10c in the fourth embodiment of the present invention. For ease of explanation, the structures in the fourth embodiment that are similar or the same as those in the third embodiment are given the same or similar numbers, and the structures in the fourth embodiment that are the same as those in the third embodiment will not be described again here.
[0126] The difference between the hinge 10c in the fourth embodiment of the present invention and the hinge 10c in the third embodiment is that: one of the fixed plate 24 and the linkage plate 25 is provided with a second clearance groove 244, and the other is provided with a convex shaft that cooperates with the second clearance groove 244. The second clearance groove 244 is an arc-shaped groove with the hinge shaft 21 as the center. The convex shaft cooperates with the second clearance groove 244, so that the fixed plate 24 can rotate independently around the hinge shaft 21 relative to the linkage plate 25.
[0127] In one specific embodiment, when the door 30 is in the closed state, the convex shaft engages with the second clearance groove 244. That is, when the movable seat 2c rotates around the hinge axis 21 in a direction away from the fixed seat 1, with the engagement of the convex shaft and the second clearance groove 244, the fixed plate 24 first rotates around the hinge axis 21 in place by a preset angle, and then the fixed plate 24 enters a linked state with the linkage plate 25. Thus, when opening the door, the door 30 can first rotate around the hinge axis 21 in a direction away from the housing 20 by a preset angle, and in the final stage of closing the door, the door 30 can rotate around the hinge axis 21 in a direction closer to the housing 20 by a preset angle. This is suitable for doors 30 with a flip beam and makes it easier to open and close the door 30.
[0128] It is understood that the aforementioned preset angle is determined by the length of the clearance groove.
[0129] In one specific embodiment, the second clearance groove 244 is provided on the fixed plate 24, and the convex shaft is the first rotating shaft 321, which simplifies the structure of the hinge 10c.
[0130] In an embodiment where the second clearance groove 244 is provided on the fixed plate 24 and the fixed plate 24 is provided with the third sliding groove 241, the second clearance groove 244 is provided at one end of the third sliding groove 241 away from the hinge shaft 21, and the second clearance groove 244 is connected to the third sliding groove 241.
[0131] It is understood that in this embodiment, the alignment structure 4 is achieved after the fixed plate 24 rotates around the hinge axis 21 toward the fixed seat 1 until the first rotating shaft 321 enters the second clearance groove 244 from the third sliding groove 241, thereby aligning the fixed plate 24 with the linkage plate 25.
[0132] The hinge 10c in the fourth embodiment of the present invention is the same as the hinge 10b in the third embodiment except for the differences mentioned above, and will not be described again here.
[0133] Furthermore, the present invention also provides a refrigeration device 100, the refrigeration device 100 including a housing 20, a door 30 for opening and closing the housing 20, and a hinge 10c for connecting the housing 20 and the door 30.
[0134] The hinge 10c is the hinge 10c in the fourth embodiment of the present invention, and will not be described again here.
[0135] In this embodiment, the refrigeration device 100 is a vertical refrigerator with left and right doors. Of course, it should be emphasized that the refrigeration device 100 can also be a vertical refrigerator with top and bottom doors or a horizontal freezer, etc.
[0136] The opening and closing process of the refrigeration device 100 with the hinge 10c is described below:
[0137] When the door 30, which is in a closed state, is opened, the door 30 first rotates around the hinge axis 21 by a preset angle until the fixed plate 24 is in a linked state;
[0138] After the fixed plate 24 and the linkage plate 25 are in a linked state, the door body 30 continues to rotate around the hinge axis 21 in a direction away from the box body 20, while moving inward a preset distance with the slider 12 under the action of the linkage component 3;
[0139] After the door body 30 has moved inward, the fixing plate 24 is in a detachable state, and the door body 30 can rotate freely around the hinge axis 21 in place;
[0140] When the door 30 is closed from the open state, the door 30 first rotates around the hinge axis 21 in place toward the direction of the box 20 until the fixed plate 24 and the linkage plate 25 are in a linked state.
[0141] After the door is closed until the fixed plate 24 and the linkage plate 25 are in a linked state, the door body 30 rotates around the hinge axis 21 in a direction closer to the box body 20. At the same time, under the action of the linkage component 3, it moves outward a preset distance with the slider 12 until the fixed plate 24 and the linkage plate 25 are in a non-linked state.
[0142] After the fixed plate 24 and the linkage plate 25 are in a non-linked state, the door 30 rotates in place around the hinge axis 21 toward the box 20 by a preset angle and then the door 30 is in a closed state.
[0143] It is understandable that during the opening process, the door body 30 mentioned above first rotates around the hinge axis 21 at a preset angle until the fixed plate 24 and the linkage plate 25 are in a linked state. That is, the door body 30 rotates around the hinge axis 21 until the first rotating shaft 321 enters the third sliding groove 241 from the second clearance groove 244. At this time, the third sliding groove 241 is aligned with the second sliding groove 22.
[0144] The preset distances for the inward and outward movement of the door 30 can be preset by adjusting the length of the first slide groove 11.
[0145] The completion of the inward movement of the aforementioned door body 30 means that the slider 12 moves to the inner end, and the first rotating shaft 321 is located at the notch 242.
[0146] The aforementioned closing of the door to the point where the fixed plate 24 and the linkage plate 25 are in a linked state means that the door is closed to the point where the first rotating shaft 321 enters the third sliding groove 241 through the notch 242. At this time, the third sliding groove 241 is aligned with the second sliding groove 22.
[0147] The aforementioned fixed plate 24 and the linkage plate 25 are in a non-linked state, that is, during the closing process, the first rotating shaft 321 enters the second clearance groove 244 from the third sliding groove 241.
[0148] In summary, the hinge 10 of the present invention, by setting a linkage component 3, which is used to link the slider 12 on the fixed seat 1 and the movable seat 2, can control the movement trajectory of the door 30, enhance the versatility of the door 30, and enable the door 30 to adapt to various application scenarios, such as the application scenario of embedded refrigerators.
[0149] The above embodiments are only used to illustrate the technical solutions of the present invention and are not intended to limit it. Although the present invention has been described in detail with reference to preferred embodiments, for example, if the technologies in different embodiments can be used in combination to achieve the corresponding effects simultaneously, the solutions are also within the protection scope of the present invention. Those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention.
Claims
1. A hinge for connecting a door to a housing; characterized in that, The hinge includes: A fixed base is fixed to the housing, and the fixed base has a first sliding groove and a slider that is slidably connected to the first sliding groove. A movable seat is connected to the door body, and one end of the movable seat is connected to a hinge shaft; A linkage component is provided between the slider and the movable seat. When the movable seat rotates open about the hinge axis away from the fixed seat, the linkage component drives the slider to move along the first slide groove, thereby causing the movable seat to move a preset distance in the same direction. The movable seat is provided with a second slide groove extending along the length direction of the movable seat. The linkage component has a first rotating shaft that cooperates with the second slide groove. When the movable seat is rotated open in a direction away from the fixed seat, causing the linkage component to drive the slider to move along the first slide groove, the first rotating shaft moves to one end of the second slide groove near the hinge shaft.
2. A hinge for connecting a door to a housing; characterized in that, The hinge includes: A fixed base is fixed to the housing, and the fixed base has a first sliding groove and a slider that is slidably connected to the first sliding groove. A movable seat is connected to the door body, and one end of the movable seat is connected to a hinge shaft; A linkage component is disposed between the slider and the movable seat. When the movable seat rotates in place by a preset angle about the hinge axis away from the fixed seat, and then continues to rotate and open away from the fixed seat, the linkage component drives the slider to move along the first slide groove, thereby causing the movable seat to move a preset distance in the same direction.
3. The hinge according to claim 2, characterized in that, The movable seat is provided with a clearance groove, and the linkage component has a first rotating shaft that cooperates with the clearance groove. The clearance groove is an arc-shaped groove with the hinge axis as the center. When the movable seat rotates around the hinge axis in a direction away from the fixed seat, the first rotating shaft cooperates with the clearance groove to make the movable seat rotate in place by a preset angle.
4. The hinge according to claim 1 or 2, characterized in that, The first slide extends along the length of the fixed seat. The first slide has an outer end close to the hinge axis and an inner end away from the hinge axis. When the movable seat rotates open about the hinge axis away from the fixed seat, the linkage component drives the slider to move from the outer end to the inner end, causing the movable seat to move in the same direction.
5. The hinge according to claim 2, characterized in that, The movable seat is provided with a second slide groove extending along the length direction of the movable seat. The linkage component has a first rotating shaft that cooperates with the second slide groove. When the movable seat is rotated open in a direction away from the fixed seat, causing the linkage component to drive the slider to move along the first slide groove, the first rotating shaft moves to one end of the second slide groove near the hinge shaft.
6. The hinge according to claim 5, characterized in that, The length of the second groove is not less than the length of the first groove.
7. The hinge according to claim 1 or 2, characterized in that, After the linkage component drives the slider to move along the first slide groove, causing the movable seat to move a preset distance in the same direction, the movable seat can rotate in place around the hinge axis.
8. The hinge according to claim 7, characterized in that, The movable seat includes a fixed plate fixed to the door body and a linkage plate rotatably connected to the fixed plate through the hinge shaft. The linkage plate is movably connected to the linkage assembly. The fixed plate has a linkage state that is fixed relative to the linkage plate and a disengaged state that can be detached from the linkage plate.
9. The hinge according to claim 7, characterized in that, The linkage component includes a telescopic rod assembly, one end of which is rotatably connected to the fixed seat and the other end is movably connected to the movable seat. The telescopic rod assembly has a non-extendable first state and a extendable second state. When the telescopic rod assembly is in the first state, as the movable seat rotates around the hinge axis, the linkage component drives the movable seat to move synchronously with the slider. When the telescopic rod assembly is in the second state, the movable seat can rotate in place around the hinge axis.
10. A refrigeration device, comprising a housing and a door, characterized in that, The refrigeration device further includes a hinge as described in any one of claims 1-9.