WO2023093317A1 - 冰箱的门体转动轴心的确定方法及冰箱 - Google Patents
冰箱的门体转动轴心的确定方法及冰箱 Download PDFInfo
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- WO2023093317A1 WO2023093317A1 PCT/CN2022/124251 CN2022124251W WO2023093317A1 WO 2023093317 A1 WO2023093317 A1 WO 2023093317A1 CN 2022124251 W CN2022124251 W CN 2022124251W WO 2023093317 A1 WO2023093317 A1 WO 2023093317A1
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- Prior art keywords
- door body
- axis
- door
- line
- trajectory line
- Prior art date
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- 238000000034 method Methods 0.000 title claims abstract description 76
- 238000009434 installation Methods 0.000 claims description 71
- 239000011521 glass Substances 0.000 claims description 8
- 238000010586 diagram Methods 0.000 description 7
- 230000009286 beneficial effect Effects 0.000 description 3
- 238000006243 chemical reaction Methods 0.000 description 2
- 238000000354 decomposition reaction Methods 0.000 description 2
- 239000004831 Hot glue Substances 0.000 description 1
- 239000000853 adhesive Substances 0.000 description 1
- 230000001070 adhesive effect Effects 0.000 description 1
- 239000002390 adhesive tape Substances 0.000 description 1
- 239000003086 colorant Substances 0.000 description 1
- 238000005034 decoration Methods 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- 230000002452 interceptive effect Effects 0.000 description 1
- 238000005057 refrigeration Methods 0.000 description 1
- 239000007787 solid Substances 0.000 description 1
- 238000006467 substitution reaction Methods 0.000 description 1
- 230000009466 transformation Effects 0.000 description 1
- 238000000844 transformation Methods 0.000 description 1
Images
Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D23/00—General constructional features
- F25D23/02—Doors; Covers
- F25D23/028—Details
-
- E—FIXED CONSTRUCTIONS
- E05—LOCKS; KEYS; WINDOW OR DOOR FITTINGS; SAFES
- E05D—HINGES OR SUSPENSION DEVICES FOR DOORS, WINDOWS OR WINGS
- E05D5/00—Construction of single parts, e.g. the parts for attachment
- E05D5/10—Pins, sockets or sleeves; Removable pins
-
- E—FIXED CONSTRUCTIONS
- E05—LOCKS; KEYS; WINDOW OR DOOR FITTINGS; SAFES
- E05D—HINGES OR SUSPENSION DEVICES FOR DOORS, WINDOWS OR WINGS
- E05D5/00—Construction of single parts, e.g. the parts for attachment
- E05D5/10—Pins, sockets or sleeves; Removable pins
- E05D5/14—Construction of sockets or sleeves
-
- E—FIXED CONSTRUCTIONS
- E05—LOCKS; KEYS; WINDOW OR DOOR FITTINGS; SAFES
- E05D—HINGES OR SUSPENSION DEVICES FOR DOORS, WINDOWS OR WINGS
- E05D7/00—Hinges or pivots of special construction
- E05D7/04—Hinges adjustable relative to the wing or the frame
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D23/00—General constructional features
- F25D23/02—Doors; Covers
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D2323/00—General constructional features not provided for in other groups of this subclass
- F25D2323/02—Details of doors or covers not otherwise covered
Definitions
- the invention relates to the field of refrigeration equipment, in particular to a method for determining the rotational axis of a door body of a refrigerator and the refrigerator.
- the object of the present invention is to provide a method for determining the rotation axis of a door body of a refrigerator and the refrigerator.
- the present invention adopts the following technical solutions: a method for determining the rotation axis of the door body of a refrigerator, the refrigerator includes a box body, and a door body connected to the box body through hinge rotation; the determination method Including the following steps:
- the target area is located on the side of the first trajectory line close to the pivoting side, and during the rotation process of the door body, it is determined that the rotation axis of the door body is located in the target area or on the boundary line of the target area.
- the target area is located on the hinge installation side of the door body.
- fitting the first trajectory specifically includes the following steps:
- the refrigerator is embedded in a cabinet, and the determination method further includes the following steps:
- the target area is located on a side of the second trajectory line away from the pivoting side at the same time.
- fitting the second trajectory specifically includes the following steps:
- the refrigerator is embedded in a cabinet, and the determination method further includes the following steps:
- the target area is located on a side of the third trajectory line close to the pivoting side at the same time.
- the refrigerator is embedded in a cabinet, and the determination method further includes the following steps:
- the target area is located on a side of the fourth trajectory line away from the pivoting side at the same time.
- the present invention also provides a refrigerator, which includes a box body and a door body that is rotatably connected to the box body through a hinge.
- the door body rotates around the rotation axis of the door body;
- the rotation axis of the door body is located in the target area or on the boundary line of the target area, and the target area is located on the side of the first trajectory line close to the pivoting side; when the rotation axis of the door body is located in the On the first trajectory line, during the rotation process of the door body, the end of the rear wall of the door body on the pivoting side is tangent to the box body.
- the target area is located on the hinge installation side of the door body.
- the first intersection line on the installation side is the X axis
- the second intersection line between the pivoting side of the door in the closed state and the hinge installation side of the door is the Y axis
- the X axis and the The intersection point of the Y axis is used as the origin to draw the curve in the XY coordinate system
- B represents the second gap between the door body and the box body when the door body is in a closed state
- T represents the distance between the door body and the box body. thickness value.
- the refrigerator is embedded in the cabinet, the target area is located on the side of the second trajectory line away from the pivoting side, and the rotation axis of the door body is located on the second trajectory
- the actual maximum opening angle of the door body is equal to the preset maximum opening angle
- the first intersection line is the X axis
- the second intersection line between the pivoting side of the door body in the closed state and the hinge installation side of the door body is the Y axis
- the intersection point of the X axis and the Y axis A straight line drawn in the XY coordinate system constructed as the origin, wherein V represents the preset maximum door opening angle, and A represents the first gap between the pivoting side of the door and the cabinet when the door is in a closed state.
- the first intersection line between the front wall of the door body in the closed state and the hinge installation side of the door body is the X axis, and the pivotal side of the door body in the closed state and the hinge installation side of the door body
- the second line of intersection is the Y axis, and the intersection of the X axis and the Y axis is used as a straight line drawn in the XY coordinate system constructed as the origin; the center of rotation of the door body is located on the third trajectory line
- the third gap between the front wall of the door and the cabinet is equal to the first gap between the pivoting side of the door and the cabinet when the door is in the closed state. gap.
- the refrigerator is embedded in the cabinet, and the target area is located on the side of the fourth track line away from the pivoting side; when the rotation axis of the door body is located on the fourth track line When on the line, after the door body is rotated to 90°, the gap between the door body and the cabinet is 0.
- the rotation axis of the door body is a solid axis or a virtual axis.
- the front wall of the door body is higher than the hinge, and the hinge has an escape portion on the pivot side.
- the door body is a glass door body.
- the beneficial effects of the present invention are: according to the method for determining the position of the door body rotation axis in the present invention, the target area of the door body rotation axis can be determined, so that debugging can be carried out in the determined target area, which can ensure that the door body is debugged no matter what. body will not interfere with the box.
- the present invention can determine the area and direction of adjustment according to the needs, so as to avoid repeated interference with the box during the adjustment process. Thereby increasing the phenomenon of debugging time.
- Fig. 1 is a partially schematic perspective view of a refrigerator according to an embodiment of the present invention.
- Fig. 2 is a schematic top view (hinge removed) of the refrigerator shown in Fig. 1 .
- Fig. 3 shows a schematic diagram of the trajectory of the first trajectory line on the hinge installation side in the method for determining the rotation axis of the door body in the present invention, wherein a circle whose center is on the first trajectory line and passes through N points is shown;
- Figure 4 shows a circle centered on the axis of rotation of the door body and passing through point D;
- Fig. 5 shows a schematic diagram of the trajectory of the second trajectory line on the hinge installation side in the method for determining the rotation axis of the door body in the present invention
- Fig. 6 shows a schematic structural diagram when the door body of the refrigerator in the present invention is rotated by 90°
- Fig. 7 shows a schematic diagram of the trajectory of the third trajectory line on the hinge installation side in the method for determining the rotation axis of the door body in the present invention
- Fig. 8 shows a schematic diagram of the trajectory of the fourth trajectory line on the hinge installation side in the method for determining the rotation axis of the door body in the present invention
- Fig. 9 shows a schematic diagram of the trajectory of the fifth trajectory line on the hinge installation side in the method for determining the rotation axis of the door body in the present invention
- Fig. 10 shows a schematic structural diagram of a refrigerator according to a second embodiment of the present invention.
- FIG. 11 is a schematic partial view of the refrigerator in FIG. 10 .
- Fig. 1 shows a partially schematic perspective view of a refrigerator according to an embodiment of the present invention.
- Fig. 2 shows a schematic top view of a refrigerator according to an embodiment of the present invention (hinges are removed), in which only one side of the cabinet 4 is shown, and in actual installation, the refrigerator is entirely embedded in the cabinet 4 .
- the refrigerator is not necessarily embedded in the cabinet 4, but also can be embedded in the wall.
- the refrigerator has the same structure as the refrigerator in the prior art, and generally includes a box body 1 and a door body 2 rotatably connected to the box body 1 through a hinge 3 .
- the door body 2 includes a front wall 22 , a hinge installation side 23 and a pivoting side 21 .
- the front wall 22 of the door body 2 is the side facing the external environment when the refrigerator is embedded in the cabinet 4 .
- the hinge installation side 23 of the door body 2 is the upper side of the door body 2, that is, one end of the hinge 3 is installed on the hinge installation side 23, and the other end of the hinge 3 is installed on the upper side of the casing 1 of the refrigerator.
- the pivoting side 21 of the door body 2 is the side where the door body 2 rotates around the box body 1 .
- the present invention provides a method for determining the rotational axis of a door body of a refrigerator, comprising the following steps:
- the target area is located on the side of the first trajectory line close to the pivoting side, and during the rotation process of the door body, it is determined that the rotation axis of the door body is located in the target area or on the boundary line of the target area.
- the above-mentioned boundary line refers to the first trajectory line.
- the aforementioned door body rotation axis is located in the target area or on the boundary line of the target area can be understood as the door body 2 rotation process, the door body rotation axis is always located in the target area. It can also be understood that during the rotation process of the door body 2, the rotation axis of the door body is in the target area and/or the target area. Move on the boundary line of the area.
- the present invention can carry out debugging in the determined target area, which can ensure that the box body 1 will not be interfered with in any case. Therefore, the phenomenon of repeatedly interfering with the cabinet 1 and increasing the debugging time during the debugging process is avoided.
- the rotation axis of the door body may be a physical axis or a virtual axis.
- the rotation axis of the door body is the axis of the rotation shaft in the single-axis hinge, that is, the physical axis.
- the rotation axis of the door body is a virtual axis defined by multiple axes in the multi-axis hinge.
- fitting the first trajectory line specifically includes the following steps:
- the first intersection line between the front wall 22 of the door body 2 in the closed state and the hinge installation side 23 of the door body 2 is the X axis
- the door body 2 in the closed state The second intersection line between the pivoting side 21 of the door body 2 and the hinge installation side 23 of the door body 2 is the Y axis
- the intersection of the X axis and the Y axis is used as the origin O to construct an XY coordinate system;
- the value range of x can also be adaptively narrowed so as to facilitate the setting of the hinge axis .
- the hinge installation side 23 of the door body 2 includes four sides, namely the front side, the rear side, the left side and the right side, wherein the front side is the side where the X-axis is located, the right side is the side where the Y-axis is located, and the front side is the side where the Y-axis is located.
- the intersection point with the right side is the origin O, and the intersection point with the right side is defined as N point.
- the N point is located at one end of the rear wall of the door body 2 located at the pivoting side 21 .
- x represents the rotation axis of the door body
- y represents the ordinate of the rotation axis of the door body.
- the graph shown in Figure 3 can be drawn The first trajectory line F. If the center of the circle is each point in the first trajectory line F, and the distance from the point of the first trajectory line F to point N is used as the radius, then the circle passing through point N will be tangent to the box body 1, that is, when the door rotates When the axis is located on the first trajectory line F, point N on the door 2 is tangent to the box body 1 during the rotation of the door body 2 .
- the circle passing through point N will overlap with the box body 1, that is, at the center of rotation of the door body
- the first trajectory line F is on the side away from the pivoting side 21 , during the rotation of the door body 2 , there is interference between the point N and the box body 1 . Therefore, it is determined that the side of the first trajectory line F close to the pivoting side is the target area, and the rotation axis of the door body is located in the target area or on the boundary line of the target area , there is no interference between the door body 2 and the box body 1 during the rotation process.
- the determination method further includes the following steps:
- the target area is located on the side of the second trajectory line away from the pivoting side 21 at the same time.
- the actual maximum opening angle of the door 2 refers to the opening of the door 2 to the interference between the door 2 and the cabinet 4 .
- the actual maximum opening angle of the door body 2 is equal to the preset maximum opening angle;
- the trajectory line is away from the side of the pivoting side 21, the actual maximum door opening angle of the door body is greater than the preset maximum door opening angle;
- the rotation axis of the door body is located near the second trajectory line
- the actual maximum opening angle of the door body is smaller than the preset maximum opening angle. Therefore, the target area is limited while being located on the side of the second trajectory line away from the pivoting side 21, so that the actual maximum opening angle of the door body 2 is not less than the preset maximum opening angle, at this time , the boundary line of the target area includes the first trajectory line and the second trajectory line.
- the rotation axis of the door body When the rotation axis of the door body is located in the target area jointly defined by the first trajectory line and the second trajectory line, the rear wall of the door body 2 is located between one end of the pivoting side 21 and the box body 1 There is a gap between them, and at the same time, the actual maximum opening angle of the door body 2 is greater than the preset maximum opening angle.
- the rotation axis of the door body is located on the first trajectory line F as the boundary line of the target area, the end of the rear wall of the door body 2 on the pivot side 21 is tangent to the box body 1, and at the same time, The actual maximum door opening angle of the door body 2 is greater than the preset maximum door opening angle.
- the technician can know the relationship between the final actual maximum door opening angle of the door body 2 and the preset maximum door opening angle according to the finally determined positional relationship between the door body rotation axis and the second trajectory line.
- the actual maximum door opening angle of the required door body 2 is not less than the maximum door opening angle, so the target area is defined as being located on the side of the second trajectory line away from the pivoting side 21 at the same time.
- fitting the second trajectory line specifically includes the following steps:
- the second intersection line of the hinge installation side 23 of the door body 2 is the Y axis, and the intersection of the X axis and the Y axis is taken as the origin, thereby constructing an XY coordinate system;
- T represents the thickness value of the door body.
- the cabinet 4 has a point D on the same horizontal line as the origin, with the center of rotation of the door body as the circle point, and the distance from the center of rotation of the door body to point D as the radius Draw a circle, the point of intersection between the circle and the front edge of the hinge installation side 23 when the door body 2 is in the closed state is point E, then the line between the axis of door rotation and point D and the line between the axis of door rotation and point E The included angle is the angle V through which the door body 2 turns.
- the second trajectory line G as shown in Figure 5 can be drawn, and it can be drawn that It is a straight line.
- the actual maximum opening angle of the door body 2 is equal to V.
- the actual maximum opening angle of the door body 2 is greater than V, and the actual maximum opening angle of the door body 2 is smaller than V when the second trajectory line G is located on the side close to the pivoting side 21 .
- the determination method also includes the following steps:
- the second intersection line of the hinge installation side 23 of the door body 2 is the Y axis, and the intersection of the X axis and the Y axis is taken as the origin, thereby constructing an XY coordinate system;
- the target area is located on a side of the third trajectory line close to the pivoting side at the same time.
- the third gap between the front wall 22 of the door body 2 and the cabinet 4 is equal to that of the door
- the rotation axis is located on the side of the third trajectory line H close to the pivoting side 21, when the door body 2 rotates to 90°, the third gap is smaller than the first gap, that is, the door When the body 2 rotates to 90°, it will move outward, which is beneficial for users to take and place items;
- the third gap is larger than the first gap, that is, the door body 2 will move inward when turning to 90°, and at this time, the door body 2 will cover part of the storage compartment
- the storage space affects the user's picking and placing of items.
- the target area is determined to be located on the side of the third trajectory line H close to the pivoting side 21, so that after the door body 2 is rotated to 90°, the storage space will not be covered, It will not affect the user to pick and place items.
- x ⁇ y.
- the third gap between the front wall 22 of the door body 2 and the cabinet 4 needs to be equal to the first gap when the door body 2 is rotated to 90°, it is necessary to The axis of rotation of the door body 2 is found on the trajectory H or the axis needs to be moved on the third trajectory H.
- the third locus H whose axis is on the hinge installation side 23 can be determined, and the axis is selected on the third locus H or on the third locus H. Moving on the trajectory line H can ensure that the gap between the door body 2 and the cabinet 4 remains unchanged when the door body 2 rotates to 90°.
- the third trajectory H, the first trajectory F, and the second trajectory G jointly define a target area.
- the target The boundary lines of the area include the second trajectory line G and the third trajectory line H.
- the rotation axis of the door body is located on the third trajectory line H as the boundary line of the target area, during the rotation of the door body 2, the rear wall of the door body 2 is located at the There is a gap between one end of the pivoting side 21 and the box body 1, the actual maximum door opening angle of the door body 2 is greater than the preset maximum door opening angle, when the door body 2 rotates to 90°, the first The first gap is equal to the third gap, that is, the distance between the door body 2 and the cabinet 4 remains unchanged.
- the third trajectory line H may also jointly define the target area with the first trajectory line F.
- the boundary line of the target area Including the first trajectory line F and the third trajectory line H.
- the location determination method also includes the following steps:
- the second intersection line of the hinge installation side 23 of the door body 2 is the Y axis, and the intersection of the X axis and the Y axis is taken as the origin, thereby constructing an XY coordinate system;
- the target area is located on the side of the fourth trajectory line away from the pivoting side 21 at the same time.
- the door body 2 protrudes from the cabinet 4 when it rotates to 90°, that is, it will be in line with the Interference occurs between the cabinets 4;
- the rotation axis of the door body is located on the side away from the pivoting side 21 on the fourth trajectory line L, when the door body rotates to 90°, the door body There is a gap between the front wall 22 of 2 and the cabinet 4. Therefore, the target area is further defined as being located on the side of the fourth trajectory line away from the pivoting side 21 at the same time, so that the built-in refrigerator can be used normally.
- x ⁇ y.
- the first trajectory line F, the third trajectory line H and the fourth trajectory line L jointly form the axis of rotation of the door body 2 in the target area or the axis needs to be moved in the cover target area.
- the target area defined by the second trajectory line G is located within the target area defined by the fourth trajectory line L and is smaller than the target area defined by the fourth trajectory line L, Therefore, the fourth trajectory line L is adapted to define a target area together with the first trajectory line F, or to define a target area together with the first trajectory line F and the third trajectory line H.
- the fourth trajectory line L, the first trajectory line F, and the third trajectory line H jointly define a target area.
- the target area The boundary lines of include the first trajectory line F, the third trajectory line H, and the fourth trajectory line L.
- the fourth trajectory line L and the first trajectory line F can also jointly define the target area. At this time, the boundary line of the target area Including the first trajectory line F and the fourth trajectory line L.
- the determination method also includes the following steps:
- the target area is located on a side of the fifth trajectory line away from the box 1 .
- the rotation axis of the door body When the rotation axis of the door body is located on the fifth trajectory line, during the rotation of the door body 2, one end of the front wall 22 of the door body located on the pivot side 21 is tangent to the cabinet 4; the door body rotates When the axis is located on the side of the fifth trajectory line away from the box body 1, there is a gap between the end of the front wall 22 of the door body 2 located on the pivot side 21 and the cabinet 4, and the rotation axis of the door body is When the center is located on the side of the fifth trajectory line close to the box body 1 , the front wall 22 of the door body 2 collides with the cabinet 4 at the end on the pivoting side 21 . Therefore, it is further defined that the target area is located on the side of the fifth trajectory line away from the box body 1 so that there is no interference between the door body 2 and the cabinet during the rotation of the door body 2 .
- the rotation axis of the door body is always located in the target area, thereby ensuring that the position of the rotation axis center of the door body can ensure that the door body 2 does not interfere with the cabinet 4 during the rotation process. and box 1.
- the present invention can be adjusted in the determined target area, and can ensure that the adjustment will not interfere with the cabinet 4 and cabinets no matter what. Body 1, so as to avoid repeated interference with the cabinet 4 and/or box 1 during the debugging process, thereby increasing the debugging time.
- fitting the fifth trajectory line specifically includes the following steps:
- the second intersection line of the hinge installation side 23 of the door body 2 is the Y axis, and an XY coordinate system is constructed with the intersection of the X axis and the Y axis as the origin;
- the fifth trajectory line is drawn in the XY coordinate system, wherein, as shown in Figure 2, A represents the door body 2 when the door body 2 is in a closed state The first gap between the pivoting side 21 and the cabinet 4.
- the value range of y can also be adaptively expanded, such as -T/2 ⁇ y ⁇ T; Or the range of y can also be set so that the target area is located on the hinge installation side 23 of the door body 2 in the closed state, so as to facilitate the setting of the hinge axis.
- the fifth gap shown in Figure 9 can be drawn. Trajectory line E. If the center of the circle is each point in the first locus E, then the distance from the point on the fifth locus E to the origin is used as the radius, and the circle passing through the origin will be tangent to the cabinet 4, that is, at the center of rotation of the door body When located on the fifth trajectory line E, during the rotation of the door body 2 , the end of the front wall 22 of the door body 2 on the pivoting side 21 is tangent to the cabinet 4 .
- the target area defined by the fifth trajectory line E is located within the target area defined by the fourth trajectory line L and is smaller than the target area defined by the fourth trajectory line L. Therefore, in the embodiment with the fifth trajectory line E, the fourth trajectory line L may not be considered.
- the fifth trajectory line E and the first trajectory line F may jointly define a target area, and at this time, the boundary line includes the fifth trajectory line E and the first trajectory line F.
- the fifth trajectory line E can define a target area together with the first trajectory line F and the second trajectory line G.
- the boundary line includes the fifth trajectory line E, the first trajectory line F and The second trajectory line G.
- the fifth trajectory line E may jointly define a target area together with the first trajectory line F and the third trajectory line H, and at this time, the boundary line includes the fifth trajectory line E and the third trajectory line H.
- the fifth trajectory line E can define a target area together with the first trajectory line F, the second trajectory line G, and the third trajectory line H.
- the boundary line includes the second trajectory line G, The third trajectory line H.
- the present invention also provides a built-in refrigerator embedded in the cabinet 4 .
- the built-in refrigerator includes a box body 1 and a door body 2 rotatably connected to the box body 1 through a hinge 3.
- the door body 2 rotates around the rotation axis of the door body.
- the rotation axis of the door body is set in the target area or on the boundary line of the target area.
- the method for determining the target area is determined by the above-mentioned method for determining the position of the rotation axis of the door body, and will not be repeated here.
- the rotation axis of the door body may be a physical axis or a virtual axis.
- the rotation axis of the door body is the axis of the rotation shaft in the single-axis hinge, that is, the physical axis.
- the rotation axis of the door body is a virtual axis defined by multiple axes in the multi-axis hinge.
- the method for determining the door rotation axis of a built-in refrigerator in an embodiment under certain specific requirements will be described by taking the door rotation axis as the physical axis as an example.
- the line segment between the intersection point P1 of the third trajectory line H and the second trajectory line G and the origin is defined as the first line segment.
- the coordinates of point P1 can be obtained as (-5.46, 5.46), considering the diameter and strength requirements of the hinge shaft, the diameter of the hinge shaft is set to be greater than or equal to 6mm, In addition, considering the installation of the hinge shaft on the door body 2, the point P1 is finally selected as the pivot point of the door body rotation.
- the door body 2 does not interfere with the cabinet 4 and the cabinet body 1 during the rotation around the point P1, and the maximum opening angle is 120°, meanwhile, the door body 2 will not move inward when it is opened to 90°.
- the door hinge device 3 includes an upper hinge device 33 and a lower hinge device 34 .
- the upper hinge device 33 and the lower hinge device 34 each have a hinge seat 31 and a hinge shaft 32 .
- the above hinge device 33 will be described as an example below.
- the lower hinge device 34 can be designed according to the installation form of the upper hinge device 33 on the door body 2 and the box body 1 .
- the front wall 22 of the door body 2 is higher than the hinge 3 to achieve the purpose of concealing the hinge 3 . It is beneficial to the overall appearance effect of the embedded refrigerator.
- the top side of the door body 2 (ie, the hinge installation side 23 ) is located higher than the top side of the box body 1 , and the hinge installation side 23 on the top side of the door body 2 has a groove 231 .
- the hinge base 31 of the upper hinge device 33 straddles the top side of the box body 1 and the groove 231 of the door body 2 to hide the upper door body hinge device 3 at the rear side of the door body 2 .
- the groove 231 runs through the pivoting side 21 of the door body 2, the hinge installation side 23 on the upper side and the rear side, that is to say, the groove 231 does not run through the front side 22 of the door body 2.
- the groove 231 cannot be seen, so that the upper door hinge device 3 cannot be seen, and then the upper door hinge device 3 is hidden in the groove 231, ensuring that the door body 2 aesthetics.
- the hinge seat 31 of the upper hinge device 33 can be configured as a rectangle, and a long side of the rectangular structure is aligned with the top side outer edge of the box body 1, and is also aligned with the top side outer edge of the door body 2 when the door body 2 is in a closed state. Align the edges. It can be understood that, since the groove 231 of the door body 2 does not pass through the front side 22 of the door body 2, the side of the hinge seat 31 located at the pivoting side 23 has a evacuation portion as shown in FIG. 11 311 , the escape portion 311 can avoid the front wall 22 of the door body 2 when the door body 2 is opened to a large angle, so as to smoothly install the hinge seat 31 on the top side of the box body 1 and the door body 2 .
- the hinge shaft 32 in order to avoid assembly interference between the upper hinge device 33 and the door body 2 , compared with the first embodiment, the hinge shaft 32 needs to be closer to the box body 1 .
- the hinge axis 32 is arranged on the connecting line between the intersection point of the fifth trajectory line E and the third trajectory line H and the intersection point P1.
- a door body rotation axis position point is determined on the line, for example, the coordinates are (-9,9), and the door opening angle can reach 110.5°, that is, in the second embodiment of the present invention, according to the specific application
- the actual maximum opening angle of the door body 2 is smaller than the preset maximum opening angle.
- the ordinate 9 in the above coordinates can be kept unchanged, and the abscissa can be moved to the left to the second The side on the trajectory line or the second trajectory line is away from the pivoting side 21 .
- the coordinates of the door rotation axis can be selected as (-11.59,9).
- the door body 2 is a glass door body. It is more resistant to scratches, and the glass door body has various designs and colors, which can be matched with furniture at will.
- the door plastic trim strip that fixes the glass door body also needs to have a certain wall thickness. Adhesive gaps for adhesive tape or hot melt adhesive need to be set. Therefore, for the glass door body, the hinge axis needs to be far away from the front wall 22 of the door body 2 .
- the side of the fifth trajectory line E away from the box body 1, the side of the first trajectory line F towards the pivoting side 21, and the side of the second trajectory line G away from the pivoting side 21 can be One side
- the third trajectory line H is away from the overlapping area of the side of the pivoting side 21 or on the second trajectory line G in the overlapping area to determine the position of the door body rotation axis, for example, the door can be selected
- the coordinates of the body rotation axis are (-15,11).
- the target area of the door body rotation axis can be determined, so that debugging can be carried out in the determined target area, which can ensure that the door body 2 is debugged no matter what. Neither will interfere with box 1.
- the present invention can determine the area and direction of adjustment according to the needs, so as to avoid repeated interference with the box during the adjustment process. Thereby increasing the phenomenon of debugging time.
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Abstract
提供一种冰箱的门体转动轴心的确定方法及冰箱,确定方法包括如下步骤:拟合出第一轨迹线,在门体转动轴心位于第一轨迹线上时,门体转动过程中门体(2)的后壁位于枢转侧(21)的一端与所述箱体(1)相切;确定目标区域位于第一轨迹线靠近枢转侧(21)的一侧,确定门体(2)转动过程中门体转动轴心位于目标区域内或者位于目标区域的边界线上。
Description
本发明涉及制冷设备领域,尤其涉及一种冰箱的门体转动轴心的确定方法及冰箱。
随着社会的发展,生活品质的逐步提高,人们对冰箱的美观性需求也日益突出。将冰箱嵌入橱柜,即形成嵌入式冰箱以实现装修风格统一化的家装方式已趋于流行。
现有的嵌入式冰箱中的门体在转动过程中门体转动轴心不合适时,只能通过技术人员根据自己的经验去调节,调节时由于需要不断地在各个位置去尝试导致调节时长较长,并且极大可能无法调节到最佳位置。
有鉴于此,有必要提供一种新的冰箱的门体转动轴心的确定方法及冰箱以解决上述问题。
发明内容
本发明的目的在于提供一种冰箱的门体转动轴心的确定方法及冰箱。
为实现上述发明目的,本发明采用如下技术方案:一种冰箱的门体转动轴心的确定方法,所述冰箱包括箱体、与所述箱体通过铰链转动连接的门体;所述确定方法包括如下步骤:
拟合出第一轨迹线,在所述门体转动轴心位于所述第一轨迹线上时,门体转动过程中,所述门体的后壁位于枢转侧的一端与所述箱体相切;
确定目标区域位于所述第一轨迹线靠近所述枢转侧的一侧,在门体转动过程中,确定门体转动轴心位于所述目标区域内或者位于所述目标区域的边界线上。
作为本发明进一步改进的技术方案,门体处于关闭状态时,所述目标区域位于所述门体的铰链安装侧上。
作为本发明进一步改进的技术方案,“拟合出第一轨迹线”具体包括如下步骤:
以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点,从而构建XY坐标系;
按照公式y=T-(x
2-B
2)/2B在所述XY坐标系内绘制出所述第一轨迹线,其中,B表示门体处于关闭状态时所述门体与所述箱体之间的第二间隙,T表示所述门体的厚度值。
作为本发明进一步改进的技术方案,公式y=T-(x
2-B
2)/2B中x的范围为:0≤x≤L,其中,L表示所述门体的宽度值。
作为本发明进一步改进的技术方案,所述冰箱嵌入橱柜内,所述确定方法还包括如下步骤:
获取所述门体的预设最大开门角度;
拟合出第二轨迹线,在所述门体转动轴心位于所述第二轨迹线上时,所述门体的实际最大开门角度等于所述预设最大开门角度;
确定所述目标区域同时位于所述第二轨迹线远离所述枢转侧的一侧。
作为本发明进一步改进的技术方案,“拟合出第二轨迹线”具体包括如下步骤:
以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点,从而构建XY坐标系;
按照公式x=y*tanV/2-A在所述XY坐标系内绘制所述第二轨迹线,其中,V表示所述预设最大开门角度,A表示门体处于关闭状态时所述门体的枢转侧与橱柜之间的第一间隙。
作为本发明进一步改进的技术方案,公式x=y*tanV/2-A中y的范围为-T/2≤y≤T,其中,T表示所述门体的厚度值。
作为本发明进一步改进的技术方案,所述冰箱嵌入橱柜内,所述确定方法还包括如下步骤:
以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点,从而构建XY坐标系;
按照公式x=y在所述XY坐标系内绘制第三轨迹线;在所述门体转动轴心位于所述第三轨迹线上时,所述门体转动至90°时所述门体的前壁与所述橱柜之间的第三间隙等于门体处于关闭状态时所述门体的枢转侧与橱柜之间的第一间隙;
确定所述目标区域同时位于所述第三轨迹线靠近所述枢转侧的一侧。
作为本发明进一步改进的技术方案,所述冰箱嵌入橱柜内,所述确定方法还包括如下步骤:
以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点,从而构建XY坐标系;
按照公式x=-y+A在所述XY坐标系内绘制第四轨迹线;在所述门体转动轴心位于所述第四轨迹线上时,所述门体转动至90°时所述门体与所述橱柜之间的间隙为0;
确定所述目标区域同时位于所述第四轨迹线远离所述枢转侧的一侧。
为实现上述发明目的,本发明还提供一种冰箱,包括箱体、与所述箱体通过铰链转动连接的门体,在开关门体过程中,所述门体绕门体转动轴心转动;所述门体转动轴心位于目标区域内或者位于所述目标区域的边界线上,所述目标区域位于第一轨迹线靠近枢转侧的一侧;在所述门体转动轴心位于所述第一轨迹线上时,门体转动过程 中,所述门体的后壁位于枢转侧的一端与所述箱体相切。
作为本发明进一步改进的技术方案,所述门体处于关闭状态时,所述目标区域位于所述门体的铰链安装侧上。
作为本发明进一步改进的技术方案,所述第一轨迹线是按照公式y=T-(x
2-B
2)/2B在以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点构建的XY坐标系内绘制出的曲线,其中,B表示门体处于关闭状态时所述门体与所述箱体之间的第二间隙,T表示所述门体的厚度值。
作为本发明进一步改进的技术方案,所述冰箱嵌入橱柜内,所述目标区域同时位于第二轨迹线远离所述枢转侧的一侧,在所述门体转动轴心位于所述第二轨迹线上时,所述门体的实际最大开门角度等于预设最大开门角度。
作为本发明进一步改进的技术方案,所述第二轨迹线是按照公式x=y*tanV/2-A在以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点构建的XY坐标系内绘制出的直线,其中,V表示所述预设最大开门角度,A表示门体处于关闭状态时所述门体的枢转侧与橱柜之间的第一间隙。
作为本发明进一步改进的技术方案,所述冰箱嵌入橱柜内,所述目标区域同时位于第三轨迹线靠近所述枢转侧的一侧,所述第三轨迹线是按照公式x=y在以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点构建的XY坐标系内绘制出的直线;在所述门体转动轴心位于所述第三轨迹线上时,所述门体转动至90°时所述门体的前壁与所述橱柜之间的第三间隙等于门体处于关闭状态时所述门体的枢转侧与橱柜之间的第一间隙。
作为本发明进一步改进的技术方案,所述冰箱嵌入橱柜内,所述目标区域同时位于第四轨迹线远离所述枢转侧的一侧;在所述门体转动轴心位于所述第四轨迹线上时,门体转动至90°后,所述门体与橱柜之间的间隙为0。
作为本发明进一步改进的技术方案,所述第四轨迹线是按照公式x=-y+A在以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点构建的XY坐标系内绘制出的曲线,其中,A表示门体处于关闭状态时所述门体的枢转侧与橱柜之间的第一间隙。
作为本发明进一步改进的技术方案,所述门体转动轴心为实体轴心或者虚拟轴心。
作为本发明进一步改进的技术方案,所述门体的前壁高于所述铰链,所述铰链位于所述枢转侧的一侧具有避让部。
作为本发明进一步改进的技术方案,所述门体为玻璃门体。
本发明的有益效果是:根据本发明中的门体转动轴心的位置确定方法可以确定出门体转动轴心的目标区域,从而,可以在确定的目标区域内进行调试,能够保证无论如何调试门体都不会干涉箱体。与现有技术中人为地根据经验不断调试来确定合适的门体转动轴心的方式相比,本发明可以根据需要来确定调试的区域以及调试方向,从而避免在调试过程中反复出现干涉箱体从而增加调试时间的现象。
图1是本发明一个实施例的冰箱的部分示意性立体图。
图2是图1所示的冰箱的示意性俯视图(去除铰链)。
图3示出了本发明中的门体转动轴心的确定方法中的第一轨迹线在铰链安装侧的轨迹示意图,其中示出了圆心在该第一轨迹线上且经过N点的圆;
图4示出了以门体转动轴心为圆心且经过D点的圆;
图5示出了本发明中的门体转动轴心的确定方法中的第二轨迹线在铰链安装侧的轨迹示意图;
图6示出了本发明中的冰箱的门体转动90°时的示意性结构图;
图7示出了本发明中的门体转动轴心的确定方法中的第三轨迹线在铰链安装侧的轨迹示意图;
图8示出了本发明中的门体转动轴心的确定方法中的第四轨迹线在铰链安装侧的轨迹示意图;
图9示出了本发明中的门体转动轴心的确定方法中的第五轨迹线在铰链安装侧的轨迹示意图;
图10示出了根据本发明第二实施方式中的冰箱的示意性结构图;
图11为图10中的冰箱的示意性局部图。
以下将结合附图所示的各实施方式对本发明进行详细描述,请参照图1-图11所示,为本发明的较佳实施方式,其中自始至终相同或类似的标号表示相同或类似的元件或具有相同或类似功能的元件。但应当说明的是,这些实施方式并非对本发明的限制,本领域普通技术人员根据这些实施方式所作的功能、方法、或者结构上的等效变换或替代,均属于本发明的保护范围之内。
在本发明的描述中,术语“上”、“下”、“前”、“后”等指示的方位或位置关系为基于附图所示的方位或位置关系,仅是为了便于描述本发明而不是要求本发明必须以特定的方位构造和操作,因此不能理解为对本发明的限制。例如,在下面的描述中,图2中的下侧为前,上侧为后。
图1示出了根据本发明一个实施例的冰箱的部分示意性立体图。图2示出了根据本发明一个实施例的冰箱的示意性俯视图(去除铰链),其中仅示出一侧的橱柜4,实际安装中, 冰箱是整个嵌入橱柜4中的。可以理解的是,冰箱不一定是嵌入橱柜4内,也可以是嵌入墙体内。如图1和图2所示,该冰箱与现有技术中的冰箱结构保持一致,一般性地包括箱体1和与箱体1通过铰链3转动连接的门体2。该门体2包括前壁22、铰链安装侧23和枢转侧21,该门体2的前壁22为冰箱在嵌入橱柜4时面向外部环境的一侧。该门体2的铰链安装侧23为门体2的上侧,即铰链3的一端是安装在该铰链安装侧23的,铰链3的另一端安装在冰箱的箱体1的上侧。该门体2的枢转侧21为门体2绕箱体1转动的一侧。
本发明提供一种冰箱的门体转动轴心的确定方法,包括如下步骤:
拟合出第一轨迹线,在所述门体转动轴心位于所述第一轨迹线上时,门体转动过程中,所述门体的后壁位于枢转侧的一端与所述箱体相切;
确定目标区域位于所述第一轨迹线靠近所述枢转侧的一侧,在门体转动过程中,确定门体转动轴心位于所述目标区域内或者位于所述目标区域的边界线上。
可以理解的是,在仅有所述第一轨迹线的实施方式中,上述的边界线即指所述第一轨迹线。
需要说明的是,上述的门体转动轴心位于所述目标区域内或者位于所述目标区域的边界线上可以理解为门体2转动过程中,所述门体转动轴心始终位于所述目标区域内的一个点上或者始终位于所述目标区域的边界线的一个点上;也可以理解为门体2转动过程中,所述门体转动轴心在所述目标区域和/或所述目标区域的边界线上移动。
在所述门体转动轴心位于由所述第一轨迹线限定的所述目标区域内时,门体2转动过程中,所述门体2的后壁位于枢转侧21的一端与箱体1之间具有间隙,从而,所述门体2不会与所述箱体1产生碰撞等其他干涉。与现有技术中人为地根据经验不断调试来确定合适的门体转动轴心的方式相比,本发明可以在确定的目标区域内进行调试,能够保证无论如何调试都不会干涉箱体1,从而避免在调试过程中反复出现干涉箱体1从而增加调试时间的现象。
具体地,所述门体转动轴心可以为实体轴心也可以为虚拟轴心。如,在所述铰链3为单轴铰链时,所述门体转动轴心即为所述单轴铰链中的转轴的轴心,即为实体轴心。在所述铰链3为多轴铰链时,所述门体转动轴心即为由所述多轴铰链中的多轴限定出的虚拟轴心。
进一步地,上述“拟合出第一轨迹线”具体包括如下步骤:
如图3所示,以处于关闭状态下的所述门体2的前壁22与门体2的铰链安装侧23的第一交线为X轴,以处于关闭状态下的所述门体2的枢转侧21与门体2的铰链安装侧23的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点O,构建XY坐标系;
按照公式y=T-(x
2-B
2)/2B在所述XY坐标系内绘制出所述第一轨迹线,其中,如图2所示,B表示门体处于关闭状态时所述门体与所述箱体之间的第二间隙,T表示所述门体的厚度值。
进一步地,公式y=T-(x
2-B
2)/2B中x的范围0≤x≤L,其中,L表示所述门体的宽度值。以使确定出的所述目标区域位于处于关闭状态时的门体的宽度值范围内。当然,并不以此为限,在所述门体转动轴心设置于处于关闭状态时的铰链安装侧23上时,也可以适应性缩小所述x的取值范围,以便于铰链轴的设置。
具体地,如图2所示,所述门体2的铰链安装侧23包括四条边,分别为前边、后边、左边和右边,其中,前边为X轴所在边,右边为Y轴所在边,前边与右边的交点为原点O,后边与右边的交点定义为N点。
可以理解的是,所述N点位于所述门体2的后壁位于所述枢转侧21的一端。
其中,公式y=T-(x
2-B
2)/2B的获得方法是:设定门体转动轴心在XY坐标系上的坐标为 (x,y),其中,x表示门体转动轴心的横坐标,y表示门体转动轴心的纵坐标。如图3所示,假设门体2的门体转动轴心到N点的距离为R
2,且轴心到后边的距离为C,则门体2在转动过程中,N点在围绕轴心(x,y)半径为R
2的圆上运动,为了避免门体2与箱体1干涉,则要保证N点不与箱体1干涉,因此需要满足以下条件:R
2-C≤B,y=T-C且x
2+C
2=R
2
2,取R
2-C=B,则经过换算可得:由此可得:x
2+C
2=(C+B)
2,分解公式可得:C=(x
2-B
2)/2B,将其代入y=T-C可得公式y=T-(x
2-B
2)/2B。
可以理解的是,在R
2-C=B时,门体2转动过程中,门体2上的N点与箱体1相切。
假设门体2的厚度值T和第二间隙B为固定值,那么根据公式y=T-(x
2-B
2)/2B以及x的范围0≤x≤L可以绘制出图3所示的第一轨迹线F。若圆心为第一轨迹线F中各个点,以第一轨迹线F的点到N点的距离作为半径,则通过N点的圆都会与箱体1相切,即,在所述门体转动轴心位于所述第一轨迹线F上时,门体2转动过程中,所述门体2上的N点与箱体1相切。而若圆心处于第一轨迹线F靠近所述枢转侧21的一侧的某一点时,通过N点的圆则会与箱体1之间有间隙,即,在所述门体转动轴心位于所述第一轨迹线F靠近所述枢转侧21的一侧时,门体2转动过程中,所述N点与所述箱体1之间有间隙。而若圆心处于第一轨迹线F远离所述枢转侧21的一侧的某一点时,通过N点的圆则会与箱体1之间有重叠,即,在所述门体转动轴心位于所述第一轨迹线F远离所述枢转侧21的一侧时,门体2转动过程中,所述N点与所述箱体1之间有干涉。故,确定位于所述第一轨迹线F靠近所述枢转侧的一侧为所述目标区域,在所述门体转动轴心位于所述目标区域内或者位于所述目标区域的边界线上时,所述门体2转动过程中与所述箱体1之间无干涉。
进一步地,在所述冰箱嵌入橱柜4内,即,所述冰箱为嵌入式冰箱时,所述确定方法还包括如下步骤:
获取所述门体2的预设最大开门角度;
拟合出第二轨迹线,在所述门体转动轴心位于所述第二轨迹线上时,所述门体2的实际最大开门角度等于所述预设最大开门角度;
确定所述目标区域同时位于所述第二轨迹线远离所述枢转侧21的一侧。
可以理解的是,在所述冰箱为嵌入式冰箱时,所述门体2的实际最大开门角度是指所述门体2打开至所述门体2与橱柜4之间相干涉。
在所述门体转动轴心位于所述第二轨迹线上时,所述门体2的实际最大开门角度等于所述预设最大开门角度;在所述门体转动轴心位于所述第二轨迹线远离所述枢转侧21的一侧时,所述门体的实际最大开门角度大于所述预设最大开门角度;在所述门体转动轴心位于所述第二轨迹线靠近所述枢转侧21的一侧时,所述门体的实际最大开门角度小于所述预设最大开门角度。从而,限定所述目标区域同时位于所述第二轨迹线远离所述枢转侧21的一侧,以使所述门体2的实际最大开门角度不小于所述预设最大开门角度,此时,所述目标区域的边界线包括所述第一轨迹线以及所述第二轨迹线。
所述门体转动轴心位于由所述第一轨迹线以及第二轨迹线共同限定的目标区域内时,所述门体2的后壁位于枢转侧21的一端与所述箱体1之间具有间隙,同时,所述门体2的实际最大开门角度大于所述预设最大开门角度。在所述门体转动轴心位于作为目标区域的边界 线的第一轨迹线F上时,所述门体2的后壁位于枢转侧21的一端与所述箱体1相切,同时,所述门体2的实际最大开门角度大于所述预设最大开门角度。在所述门体转动轴心位于作为目标区域的边界线的第二轨迹线上时,所述门体2的后壁位于枢转侧21的一端与所述箱体1之间具有间隙,同时,所述门体2的实际最大开门角度等于所述预设最大开门角度。
可以理解的是,技术人员能够根据最终确定的门体转动轴心与第二轨迹线的位置关系,知晓最终的门体2的实际最大开门角度与预设最大开门角度的大小关系。本实施方式中,需求门体2的实际最大开门角度不小于最大开门角度,故,将目标区域限定为同时位于所述第二轨迹线远离所述枢转侧21的一侧。
进一步地,“拟合出第二轨迹线”具体包括如下步骤:
以处于关闭状态下的所述门体2的前壁22与门体2的铰链安装侧23的第一交线为X轴,以处于关闭状态下的所述门体2的枢转侧21与门体2的铰链安装侧23的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点,从而构建XY坐标系;
按照公式x=y*tanV/2-A在所述XY坐标系内绘制所述第二轨迹线,其中,V表示所述预设最大开门角度,A表示门体处于关闭状态时所述门体的枢转侧与橱柜之间的第一间隙。
进一步地,公式x=y*tanV/2-A中y的范围0≤y≤T,其中,T表示所述门体的厚度值。以使所述门体转动轴心位于所述铰链安装侧23上当然,并不以此为限,在所述门体转动轴心设置于门体2外部的实施方式中,也可以适应性扩大所述y的取值范围,如-T/2≤y≤T。
优选地,公式x=y*tanV/2-A中,在A=3时,0≤y≤T/4;在A=4时,0≤y≤3T/10;在A=6时,0≤y≤2T/5;在A=10时,0≤y≤T/2;在A=18时,0≤y≤3T/5。
具体地,该公式x=y*tanV/2-A的获取方法是:设定门体转动轴心在XY坐标系上的坐标为(x,y),其中,x表示门体转动轴心的横坐标,y表示门体转动轴心的纵坐标。如图4所示,假设V为预设最大开门角度,橱柜4具有与原点在同一水平线上的D点,以门体转动轴心为圆点,门体转动轴心到D点的距离为半径画圆,该圆与门体2处于关闭状态时的铰链安装侧23的前边的交点为E点,则门体转动轴心与D点连线与门体转动轴心与E点连线之间的夹角即为门体2转过的角度V,另外由于处于关闭状态下的门体2的前壁22与橱柜4的前端相齐平,即D点与E点处于同一条水平线上,所以从圆心做一条垂直于门体2的前壁22线可以平分角度V,即V=2W,且tanW=(x+A)/y,分解公式可得x=y*tanV/2-A。
假设门体2的厚度值T和第一间隙A为固定值,则根据上述求解的公式及y的范围0≤y≤T可以绘制出如图5所示的第二轨迹线G,可以得出其为一直线,在门体转动轴心位于第二轨迹线G上时,门体2的实际最大开门角度等于V,位于第二轨迹线G远离所述枢转侧21的一侧时门体2的实际最大开门角度大于V,位于第二轨迹线G靠近所述枢转侧21的一侧时门体2的实际最大开门角度小于V。
进一步地,所述确定方法还包括如下步骤:
以处于关闭状态下的所述门体2的前壁22与门体2的铰链安装侧23的第一交线为X轴,以处于关闭状态下的所述门体2的枢转侧21与门体2的铰链安装侧23的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点,从而构建XY坐标系;
如图7所示,按照公式x=y在所述XY坐标系内绘制第三轨迹线H;在所述门体转动轴心位于所述第三轨迹线H上时,所述门体转动至90°时,所述门体2的前壁22与所述橱柜4 之间的第三间隙等于门体2处于关闭状态时所述门体2的枢转侧21与橱柜4之间的第一间隙;
确定所述目标区域同时位于所述第三轨迹线靠近所述枢转侧的一侧。
在所述门体转动轴心位于所述第三轨迹线H上时,所述门体转动至90°时所述门体2的前壁22与所述橱柜4之间的第三间隙等于门体2处于关闭状态时所述门体2的枢转侧21与橱柜4之间的第一间隙,即,门体2不会内移,从而不会影响用户取放物品;在所述门体转动轴心位于所述第三轨迹线H靠近所述枢转侧21的一侧时,所述门体2转动至90°时所述第三间隙小于所述第一间隙,即,所述门体2转动至90°时会外移,有利于用户取放物品;在所述门体转动轴心位于所述第三轨迹线上远离所述枢转侧21的一侧时,所述门体2转动至90°时所述第三间隙大于所述第一间隙,即,所述门体2转动至90°时会内移,此时,所述门体2会遮蔽部分储物间室的储藏空间,影响用户取放物品。故,本发明中,将所述目标区域确定为位于所述第三轨迹线H靠近所述枢转侧21的一侧,从而,门体2转动至90°后,不会遮蔽储物空间,不会影响用户取放物品。
进一步地,公式x=y的获取方法是:设定门体转动轴心在XY坐标系上的坐标为(x,y),其中,x表示门体转动轴心的横坐标,y表示门体转动轴心的纵坐标。假设x≠y。可以理解的是,如图2所示,在门体2处于关闭状态时,门体2与橱柜4之间的间隙为第一间隙A,如图6所示,在门体2转动90°时,门体2与橱柜4之间的间隙变成第三间隙A+a。若需要门体2转动后门体2与橱柜4之间的间隙不变,则需要a=0,即x=y。
因此,若需要使得所述门体2转动至90°时所述门体2的所述前壁22与所述橱柜4之间的第三间隙等于所述第一间隙,则需要在该第三轨迹线H上寻找门体2转动的轴心或者需要使得轴心在所述第三轨迹线H上移动。
根据本发明实施例的方案,按照x=y的公式可以确定出轴心在铰链安装侧23上的第三轨迹线H,将轴心选择在该第三轨迹线H上或选择在该第三轨迹线H上移动,则可以保证门体2转动至90°时门体2与橱柜4之间的间隙不变。
于图7所示的一具体实施方式中,所述第三轨迹线H与第一轨迹线F、第二轨迹线G共同限定出目标区域,此时,请参图7所示,所述目标区域的边界线包括第二轨迹线G以及第三轨迹线H。
如图7所示,在所述门体转动轴心位于所述目标区域内时,所述门体2转动过程中,所述门体2的后壁位于所述枢转侧21的一端与所述箱体1之间具有间隙,所述门体2的实际最大开门角度大于所述预设最大开门角度,所述门体2转动至90°时外移。
如图7所示,在所述门体转动轴心位于作为所述目标区域的边界线第二轨迹线G上时,所述门体2转动过程中,所述门体2的后壁位于所述枢转侧21的一端与所述箱体1之间具有间隙,所述门体2的实际最大开门角度等于所述预设最大开门角度,所述门体2转动至90°时外移。
如图7所示,在所述门体转动轴心位于作为所述目标区域的边界线第三轨迹线H上时,所述门体2转动过程中,所述门体2的后壁位于所述枢转侧21的一端与所述箱体1之间具 有间隙,所述门体2的实际最大开门角度大于所述预设最大开门角度,所述门体2转动至90°时所述第一间隙等于第三间隙,即所述门体2距所述橱柜4的距离不变。
当然,并不以此为限,于其他实施方式中,所述第三轨迹线H也可以与所述第一轨迹线F共同限定出所述目标区域,此时,所述目标区域的边界线包括所述第一轨迹线F以及第三轨迹线H。门体2转动过程中,确定所述门体转动轴心位于该目标区域内或者位于对应的边界线上,所述门体2转动过程中与所述箱体1之间无干涉,且所述门体2转动至90°时不会内移。
进一步地,所述位置确定方法还包括如下步骤:
以处于关闭状态下的所述门体2的前壁22与门体2的铰链安装侧23的第一交线为X轴,以处于关闭状态下的所述门体2的枢转侧21与门体2的铰链安装侧23的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点,从而构建XY坐标系;
如图8所示,按照公式x=-y+A在所述XY坐标系内绘制第四轨迹线L;在所述门体转动轴心位于处于目标区域内的所述第四轨迹线L上时,所述门体转动至90°时所述门体2的前壁22与所述橱柜4之间的间隙为0;
确定所述目标区域同时位于所述第四轨迹线远离所述枢转侧21的一侧。
在所述门体转动轴心位于所述第四轨迹线L上靠近所述枢转侧21的一侧时,所述门体2转动至90°时突出所述橱柜4,即,会与所述橱柜4之间产生干涉;在所述门体转动轴心位于所述第四轨迹线L上远离所述枢转侧21的一侧时,所述门体转动至90°时所述门体2的前壁22与所述橱柜4之间具有间隙。故,进一步将所述目标区域限定为同时位于所述第四轨迹线远离所述枢转侧21的一侧,以使嵌入式冰箱能够正常使用。
进一步地,公式x=-y+A的获取方法是:设定门体转动轴心在XY坐标系上的坐标为(x,y),其中,x表示门体转动轴心的横坐标,y表示门体转动轴心的纵坐标。假设x≠y。可以理解的是,如图2所示,在门体2处于关闭状态时,门体2与橱柜4之间的间隙为第一间隙A,如图6所示,在门体2转动90°时,门体2与橱柜4之间的间隙变成第三间隙A+a。若需要门体2转动后门体2与橱柜4之间无间隙,则需要a=-A,即x=-y+A。
因此,若需要使得所述门体2转动至90°时所述门体2的所述前壁22与所述橱柜4之间的间隙介于0与第一间隙之间,则需要在由所述第一轨迹线F、第三轨迹线H以及第四轨迹线L共同形成所述目标区域内寻找门体2转动的轴心或者需要使得轴心在盖目标区域内移动。
可以理解的是,所述第二轨迹线G限定出的所述目标区域位于所述第四轨迹线L限定出的目标区域之内,且小于所述第四轨迹线L限定出的目标区域,故,所述第四轨迹线L适于与所述第一轨迹线F共同限定出目标区域,或者与所述第一轨迹线F以及所述第三轨迹线H共同限定出目标区域。
于图8所示一具体实施方式中,所述第四轨迹线L与第一轨迹线F、第三轨迹线H共同限定出目标区域,此时,请参图8所示,所述目标区域的边界线包括第一轨迹线F、第三轨迹线H、第四轨迹线L。
如图8所示,在所述门体转动轴心位于所述目标区域内时,所述门体2转动过程中,所述门体2的后壁位于所述枢转侧21的一端与所述箱体1之间具有间隙,所述门体2转动至90°时外移且与所述橱柜4之间具有间隙。
如图8所示,在所述门体转动轴心位于作为所述目标区域的边界线第一轨迹线F上时,所述门体2转动过程中,所述门体2的后壁位于所述枢转侧21的一端与所述箱体1之间相切,所述门体2转动至90°时外移且与所述橱柜4之间具有间隙。
如图8所示,在所述门体转动轴心位于作为所述目标区域的边界线第三轨迹线H上时,所述门体2转动过程中,所述门体2的后壁位于所述枢转侧21的一端与所述箱体1之间具有间隙,所述门体2转动至90°时与所述橱柜4之间距离不变且与所述橱柜4之间具有间隙。
如图8所示,在所述门体转动轴心位于作为所述目标区域的边界线第四轨迹线L上时,所述门体2转动过程中,所述门体2的后壁位于所述枢转侧21的一端与所述箱体1之间具有间隙,所述门体2转动至90°时外移且与所述橱柜4之间间隙为0。
当然,并不以此为限,于其他实施方式中,所述第四轨迹线L也可以与所述第一轨迹线F共同限定出所述目标区域,此时,所述目标区域的边界线包括所述第一轨迹线F以及第四轨迹线L。
进一步地,所述确定方法还包括如下步骤:
拟合出第五轨迹线,在所述门体转动轴心位于所述第五轨迹线上时,门体2转动过程中,所述门体的前壁22位于枢转侧21的一端与橱柜4相切;
确定所述目标区域位于所述第五轨迹线远离所述箱体1的一侧。
所述门体转动轴心位于所述第五轨迹线上时,门体2转动过程中,所述门体的前壁22位于枢转侧21的一端与橱柜4相切;所述门体转动轴心位于所述第五轨迹线远离所述箱体1的一侧时,所述门体2的前壁22位于枢转侧21的一端与橱柜4之间具有间隙,所述门体转动轴心位于所述第五轨迹线靠近所述箱体1的一侧时,所述门体2的前壁22位于枢转侧21的一端与橱柜4之间相碰撞。故,进一步限定所述目标区域位于所述第五轨迹线远离所述箱体1的一侧,以使门体2转动过程中,所述门体2与所述橱柜之间无干涉。
本发明中的门体在转动的过程中,门体转动轴心始终位于所述目标区域内,从而,可以保证门体转动轴心设置的位置能够使得门体2在转动过程中不干涉橱柜4以及箱体1。与现有技术中人为地根据经验不断调试来确定合适的门体转动轴心的方式相比,本发明可以在确定的目标区域内进行调试,能够保证无论如何调试都不会干涉橱柜4以及箱体1,从而避免在调试过程中反复出现干涉橱柜4和/或箱体1从而增加调试时间的现象。
进一步地,上述的“拟合出第五轨迹线”具体包括如下步骤:
以处于关闭状态下的所述门体2的前壁22与门体2的铰链安装侧23的第一交线为X轴,以处于关闭状态下的所述门体2的枢转侧21与门体2的铰链安装侧23的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点,构建XY坐标系;
按照公式x=(y2-A2)/2A在所述XY坐标系内绘制出所述第五轨迹线,其中,如图2中所示,A表示门体2处于关闭状态时所述门体2的枢转侧21与橱柜4之间的第一间隙。
可以理解的是,上述的原点为所述门体2的前壁22位于枢转侧21的一端。
进一步地,公式x=(y
2-A
2)/2A中y的范围为:0≤y≤T,其中,T表示所述门体的厚度值。以使确定出的所述目标区域位于处于关闭状态时的门体的厚度值范围内。当然,并不以此为限,在所述门体转动轴心设置于门体外部的实施方式中,也可以适应性扩大所述y的取值范围,如-T/2≤y≤T;或者所述y的范围也可以设置为使所述目标区域位于处于关闭状态时的门体2的铰链安装侧23上,以便于铰链轴的设置。
优选地,公式x=(y
2-A
2)/2A中,在A=3时,0≤y≤T/4;在A=4时,0≤y≤3T/10;在A=6时,0≤y≤2T/5;在A=10时,0≤y≤T/2;在A=18时,0≤y≤3T/5。
其中,公式x=(y
2-A
2)/2A的获得方法是:设定门体转动轴心在XY坐标系上的坐标为(x,y),其中,x表示门体转动轴心的横坐标,y表示门体转动轴心的纵坐标。假设门体转动轴心到原点的距离为R
1,则门体2在转动过程中,原点在围绕轴心(x,y)同时半径为R
1的圆上运动,为了避免门体2与橱柜4干涉,则要保证原点不与橱柜4干涉,因此需要满足以下条件:R
1-x≤A且x
2+y
2=R
1
2,取R
1-x=A,则经过换算可得:x
2+y
2=(x+A)
2,分解公式可以得到上述公式x=(y
2-A
2)/2A。
可以理解的是,在R
1-x=A时,门体2转动过程中,所述门体的前壁22位于枢转侧21的一端与橱柜4相切。
假设门体2的厚度值T和第一间隙A为固定值,那么根据公式x=(y
2-A
2)/2A以及y的范围0≤y≤T可以绘制出图9所示的第五轨迹线E。若圆心为第一轨迹线E中各个点,则第五轨迹线E上的点到原点的距离作为半径,则通过原点的圆都会与橱柜4相切,即,在所述门体转动轴心位于所述第五轨迹线E上时,门体2转动过程中,所述门体2的前壁22位于枢转侧21的一端与橱柜4相切。而若圆心处于第五轨迹线E远离所述箱体1的一侧的某一点,通过原点的圆则会与橱柜4有间隙,即,在所述门体转动轴心位于所述第五轨迹线E远离所述箱体1的一侧时,门体2转动过程中,所述门体的前壁22位于枢转侧21的一端与橱柜4有间隙。因而,在所述门体转动轴心位于所述第五轨迹线E远离所述箱体1的一侧时,门体2的前壁22位于枢转侧21的一端与橱柜4相切或有间隙,不会与所述橱柜4干涉。
可以理解的是,所述第五轨迹线E所限定的目标区域位于所述第四轨迹线L所限定的目标区域之内,且小于所述第四轨迹线L所限定的目标区域。故,在具有所述第五轨迹线E恶的实施方式中,可不考虑所述第四轨迹线L。
所述第五轨迹线E可与所述第一轨迹线F共同限定出目标区域,此时,所述边界线包括所述第五轨迹线E、第一轨迹线F。门体转动轴心位于所述目标区域内或者边界线上时,门体2转动过程中,能够保证所述门体2与所述橱柜4以及所述箱体1之间均无干涉。
所述第五轨迹线E可与所述第一轨迹线F、第二轨迹线G共同限定出目标区域,此时,所述边界线包括所述第五轨迹线E、第一轨迹线F以及第二轨迹线G。门体转动轴心位于所述目标区域内或者边界线上时,门体2转动过程中,能够保证所述门体2与所述橱柜4以及所述箱体1之间均无干涉,且门体2的实际最大打开角度不小于预设最大打开角度。
所述第五轨迹线E可与所述第一轨迹线F、第三轨迹线H共同限定出目标区域,此时,所述边界线包括所述第五轨迹线E、第三轨迹线H。门体转动轴心位于所述目标区域内或者边界线上时,门体2转动过程中,能够保证所述门体2与所述橱柜4以及所述箱体1之间均无干涉,且门体2打开至90°时不会内移。
所述第五轨迹线E可与所述第一轨迹线F、第二轨迹线G、第三轨迹线H共同限定出目 标区域,此时,所述边界线包括所述第二轨迹线G、第三轨迹线H。门体转动轴心位于所述目标区域内或者边界线上时,门体2转动过程中,能够保证所述门体2与所述橱柜4以及所述箱体1之间均无干涉,且门体2打开至90°时不会内移,同时,门体2的实际最大打开角度不小于预设最大打开角度。
进一步地,请参图1-图2所示,本发明还提供一种嵌入式冰箱,嵌入所述橱柜4内。所述嵌入式冰箱包括箱体1、与所述箱体1通过铰链3转动连接的门体2,在开关门体2过程中,所述门体2绕门体转动轴心转动。所述门体转动轴心设置于目标区域内或者位于所述目标区域的边界线上。所述目标区域的确定方法由上述的门体转动轴心的位置确定方法进行确定,于此,不再一一赘述。
具体地,所述门体转动轴心可以为实体轴心也可以为虚拟轴心。如,在所述铰链3为单轴铰链时,所述门体转动轴心即为所述单轴铰链中的转轴的轴心,即为实体轴心。在所述铰链3为多轴铰链时,所述门体转动轴心即为由所述多轴铰链中的多轴限定出的虚拟轴心。
下面,以所述门体转动轴心为实体轴心为例,对若干具体需求下的实施方式中的嵌入式冰箱的门体转动轴心的确定方法进行阐述。
第一实施方式:
如图9所示,定义第三轨迹线H与第二轨迹线G的交点P1与原点之间的线段为第一线段。综合考虑,最终确定门体转动轴心为所述第一线段上的某一定点,或者所述门体转动轴心在所述第一线段上移动。
于一具体实施方式中,A=4,V=120°,可以求得P1点的坐标为(-5.46,5.46),考虑到铰链轴的直径强度要求,设定铰链轴直径大于或等于6mm,另考虑铰链轴在门体2上的安装,最终选定P1点为门体转动轴心点,门体2绕P1点转动过程中与橱柜4、箱体1均无干涉,且最大开门角度为120°,同时,门体2打开至90°时不会内移。
第二实施方式:
本实施方式与第一实施方式的区别在于:如图10所示,该门体铰链装置3包括上铰链装置33和下铰链装置34。上铰链装置33和下铰链装置34各自具有铰链座31和铰链轴32。以下以上铰链装置33为例进行说明,本领域技术人员可知,下铰链装置34可以按照上铰链装置33在门体2和箱体1上的安装形式进行设计。
所述门体2的前壁22高于所述铰链3,以达到隐藏设置所述铰链3的目的。有利于所述嵌入式冰箱的整体外观效果。
具体地,该门体2的顶侧(即铰链安装侧23)所在位置高于箱体1的顶侧所在位置,且门体2顶侧的铰链安装侧23具有一凹槽231。该上铰链装置33的铰链座31横跨在箱体1的顶侧和该门体2的凹槽231处,以将上门体铰链装置3隐藏于门体2的后侧。
参见图11,该凹槽231贯穿门体2的枢转侧21、上侧的铰链安装侧23和后侧,也就是说,该凹槽231并没有贯穿门体2的前侧22,在门体2处于关闭状态时,从前方观察冰箱时,无法看见该凹槽231,从而无法看到上门体铰链装置3,进而将上门体铰链装置3隐藏在该凹槽231内,保证了门体2的美观度。
该上铰链装置33的铰链座31可以构造成长方形,该长方形结构的一条长边与箱体1的顶侧外边缘对齐,且在门体2处于关闭状态时也与门体2的顶侧外边缘对齐。可以理解的是,由于该门体2的凹槽231并未贯穿门体2的前侧22,因此,该铰链座31位于所述枢转侧23的一侧具有如图11所示的避让部311,该避让部311可以在门体2打开至较大角度时,避让门体2的前壁22,以顺利将该铰链座31安装在箱体1和门体2的顶侧。
并且,该实施例中,为了避免上铰链装置33与门体2产生装配干涉,相较于第一实施方式,需要使铰链轴32更靠近所述箱体1。将铰链轴32设置于第五轨迹线E与第三轨迹线H的交点与交点P1之间的连线上。
于一具体示例中,在该连线上确定一个门体转动轴心位置点,例如坐标为(-9,9),开门角度可以达到110.5°,即本发明第二实施方式中,根据具体应用场景,门体2的实际最大开门角度小于所述预设最大开门角度。
于另一具体示例中,若要同时满足门体2的实际最大开门角度不小于所述预设最大开门角度,可以保护上述坐标中的纵坐标9不变,将横坐标向左移动至第二轨迹线上或者第二轨迹线远离所述枢转侧21的一侧。如,可以选取门体转动轴心的坐标为(-11.59,9)。
第三实施方式:
本发明中的第三实施方式与第一实施方式的区别为:所述门体2为玻璃门体。更耐划伤,且玻璃门体花色多样,可以与家具等随意搭配。
因玻璃门体的前壁22为具有一定厚度的玻璃面板,同时固定所述玻璃门体的门体塑料饰条也需要有一定的壁厚,所述门体塑料饰条与玻璃面板之间还需要设置胶带或者热熔胶的粘结间隙。故,对于玻璃门体而言,铰链轴需要距离所述门体2的前壁22距离较大。此时,可以在由第五轨迹线E远离所述箱体1的一侧、第一轨迹线F朝向所述枢转侧21的一侧、第二轨迹线G远离所述枢转侧21的一侧、第三轨迹线H远离所述枢转侧21的一侧的重叠区域内或者在所述重叠区域中的第二轨迹线G上确定门体转动轴心的位置,如,可以选取门体转动轴心的坐标为(-15,11)。
综上所述,根据本发明中的门体转动轴心的位置确定方法可以确定出门体转动轴心的目标区域,从而,可以在确定的目标区域内进行调试,能够保证无论如何调试门体2都不会干涉箱体1。与现有技术中人为地根据经验不断调试来确定合适的门体转动轴心的方式相比,本发明可以根据需要来确定调试的区域以及调试方向,从而避免在调试过程中反复出现干涉箱体从而增加调试时间的现象。
应当理解,虽然本说明书按照实施方式加以描述,但并非每个实施方式仅包含一个独立的技术方案,说明书的这种叙述方式仅仅是为清楚起见,本领域技术人员应当将说明书作为一个整体,各实施方式中的技术方案也可以经适当组合,形成本领域技术人员可以理解的其他实施方式。
上文所列出的一系列的详细说明仅仅是针对本发明的可行性实施方式的具体说明,它们并非用以限制本发明的保护范围,凡未脱离本发明技艺精神所作的等效实施方式或变更均应包含在本发明的保护范围之内。
Claims (15)
- 一种冰箱的门体转动轴心的确定方法,所述冰箱包括箱体、与所述箱体通过铰链转动连接的门体;其特征在于:所述确定方法包括如下步骤:拟合出第一轨迹线,在所述门体转动轴心位于所述第一轨迹线上时,门体转动过程中,所述门体的后壁位于枢转侧的一端与所述箱体相切;确定目标区域位于所述第一轨迹线靠近所述枢转侧的一侧,在门体转动过程中,确定门体转动轴心位于所述目标区域内或者位于所述目标区域的边界线上。
- 如权利要求1所述的冰箱的门体转动轴心的确定方法,其特征在于:门体处于关闭状态时,所述目标区域位于所述门体的铰链安装侧上。
- 如权利要求1所述的冰箱的门体转动轴心的确定方法,其特征在于:“拟合出第一轨迹线”具体包括如下步骤:以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点,从而构建XY坐标系;按照公式y=T-(x 2-B 2)/2B在所述XY坐标系内绘制出所述第一轨迹线,其中,B表示门体处于关闭状态时所述门体与所述箱体之间的第二间隙,T表示所述门体的厚度值,x的范围为:0≤x≤L,其中,L表示所述门体的宽度值。
- 如权利要求1所述的冰箱的门体转动轴心的确定方法,其特征在于:所述冰箱嵌入橱柜内,所述确定方法还包括如下步骤:获取所述门体的预设最大开门角度;拟合出第二轨迹线,在所述门体转动轴心位于所述第二轨迹线上时,所述门体的实际最大开门角度等于所述预设最大开门角度;确定所述目标区域同时位于所述第二轨迹线远离所述枢转侧的一侧。
- 如权利要求4所述的冰箱的门体转动轴心的确定方法,其特征在于:“拟合出第二轨迹线”具体包括如下步骤:以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点,从而构建XY坐标系;按照公式x=y*tanV/2-A在所述XY坐标系内绘制所述第二轨迹线,其中,V表示所述预设最大开门角度,A表示门体处于关闭状态时所述门体的枢转侧与橱柜之间的第一间隙,y的范围为-T/2≤y≤T,其中,T表示所述门体的厚度值。
- 如权利要求1所述的冰箱的门体转动轴心的确定方法,其特征在于:所述冰箱嵌入橱柜内,所述确定方法还包括如下步骤:以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点,从而构建XY坐标系;按照公式x=y在所述XY坐标系内绘制第三轨迹线;在所述门体转动轴心位于所述第三 轨迹线上时,所述门体转动至90°时所述门体的前壁与所述橱柜之间的第三间隙等于门体处于关闭状态时所述门体的枢转侧与橱柜之间的第一间隙;确定所述目标区域同时位于所述第三轨迹线靠近所述枢转侧的一侧。
- 如权利要求1所述的冰箱的门体转动轴心的确定方法,其特征在于:所述冰箱嵌入橱柜内,所述确定方法还包括如下步骤:以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点,从而构建XY坐标系;按照公式x=-y+A在所述XY坐标系内绘制第四轨迹线;在所述门体转动轴心位于所述第四轨迹线上时,所述门体转动至90°时所述门体与所述橱柜之间的间隙为0;确定所述目标区域同时位于所述第四轨迹线远离所述枢转侧的一侧。
- 一种冰箱,包括箱体、与所述箱体通过铰链转动连接的门体,在开关门体过程中,所述门体绕门体转动轴心转动;其特征在于:所述门体转动轴心位于目标区域内或者位于所述目标区域的边界线上,所述目标区域位于第一轨迹线靠近枢转侧的一侧;在所述门体转动轴心位于所述第一轨迹线上时,门体转动过程中,所述门体的后壁位于枢转侧的一端与所述箱体相切。
- 如权利要求8所述的冰箱,其特征在于:所述门体处于关闭状态时,所述目标区域位于所述门体的铰链安装侧上。
- 如权利要求8所述的冰箱,其特征在于:所述第一轨迹线是按照公式y=T-(x 2-B 2)/2B在以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点构建的XY坐标系内绘制出的曲线,其中,B表示门体处于关闭状态时所述门体与所述箱体之间的第二间隙,T表示所述门体的厚度值。
- 如权利要求8所述的冰箱,其特征在于:所述冰箱嵌入橱柜内,所述目标区域同时位于第二轨迹线远离所述枢转侧的一侧,在所述门体转动轴心位于所述第二轨迹线上时,所述门体的实际最大开门角度等于预设最大开门角度;所述第二轨迹线是按照公式x=y*tanV/2-A在以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点构建的XY坐标系内绘制出的直线,其中,V表示所述预设最大开门角度,A表示门体处于关闭状态时所述门体的枢转侧与橱柜之间的第一间隙。
- 如权利要求8所述的冰箱,其特征在于:所述冰箱嵌入橱柜内,所述目标区域同时位于第三轨迹线靠近所述枢转侧的一侧,所述第三轨迹线是按照公式x=y在以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点 构建的XY坐标系内绘制出的直线;在所述门体转动轴心位于所述第三轨迹线上时,所述门体转动至90°时所述门体的前壁与所述橱柜之间的第三间隙等于门体处于关闭状态时所述门体的枢转侧与橱柜之间的第一间隙。
- 如权利要求8所述的冰箱,其特征在于:所述冰箱嵌入橱柜内,所述目标区域同时位于第四轨迹线远离所述枢转侧的一侧;在所述门体转动轴心位于所述第四轨迹线上时,门体转动至90°后,所述门体与橱柜之间的间隙为0;所述第四轨迹线是按照公式x=-y+A在以处于关闭状态下的所述门体的前壁与门体的铰链安装侧的第一交线为X轴,以处于关闭状态下的所述门体的枢转侧与门体的铰链安装侧的第二交线为Y轴,并以所述X轴和所述Y轴的交点作为原点构建的XY坐标系内绘制出的曲线,其中,A表示门体处于关闭状态时所述门体的枢转侧与橱柜之间的第一间隙。
- 如权利要求8所述的冰箱,其特征在于:所述门体转动轴心为实体轴心或者虚拟轴心。
- 如权利要求8所述的冰箱,其特征在于:所述门体的前壁高于所述铰链,所述铰链位于所述枢转侧的一侧具有避让部;和/或所述门体为玻璃门体。
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US20030071549A1 (en) * | 2001-09-05 | 2003-04-17 | Peter Tarantik | Refrigerator and freezer |
CN1478170A (zh) * | 2000-12-04 | 2004-02-25 | �¶��ٲ���˹�ҵ繫˾ | 一种用于箱门的铰链 |
KR20100116932A (ko) * | 2009-04-23 | 2010-11-02 | 정융호 | 여닫이문 개폐장치 |
EP2835483A1 (de) * | 2013-08-06 | 2015-02-11 | Aug. Winkhaus GmbH & Co. KG | Ecklager |
KR20190070620A (ko) * | 2017-12-13 | 2019-06-21 | 엘지전자 주식회사 | 냉장고 |
CN110700712A (zh) * | 2018-07-09 | 2020-01-17 | 青岛海尔股份有限公司 | 一种用于冰箱的门体铰链装置及冰箱 |
CN211691972U (zh) * | 2019-12-19 | 2020-10-16 | 合肥雪祺电气有限公司 | 嵌入式冰箱铰链及冰箱 |
CN113701424A (zh) * | 2021-08-20 | 2021-11-26 | Tcl家用电器(合肥)有限公司 | 冰箱 |
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CN1478170A (zh) * | 2000-12-04 | 2004-02-25 | �¶��ٲ���˹�ҵ繫˾ | 一种用于箱门的铰链 |
US20030071549A1 (en) * | 2001-09-05 | 2003-04-17 | Peter Tarantik | Refrigerator and freezer |
KR20100116932A (ko) * | 2009-04-23 | 2010-11-02 | 정융호 | 여닫이문 개폐장치 |
EP2835483A1 (de) * | 2013-08-06 | 2015-02-11 | Aug. Winkhaus GmbH & Co. KG | Ecklager |
KR20190070620A (ko) * | 2017-12-13 | 2019-06-21 | 엘지전자 주식회사 | 냉장고 |
CN110700712A (zh) * | 2018-07-09 | 2020-01-17 | 青岛海尔股份有限公司 | 一种用于冰箱的门体铰链装置及冰箱 |
CN211691972U (zh) * | 2019-12-19 | 2020-10-16 | 合肥雪祺电气有限公司 | 嵌入式冰箱铰链及冰箱 |
CN113701424A (zh) * | 2021-08-20 | 2021-11-26 | Tcl家用电器(合肥)有限公司 | 冰箱 |
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