CN214419642U - Edge covering mechanism capable of imitating hand-shaped grabbing - Google Patents

Abstract

The utility model provides a hand-shaped grabbing-imitated edge covering mechanism, which is used for covering a transition edge adhered to an automobile handrail framework, wherein the transition edge is S-shaped in the horizontal direction and the vertical direction, and has the characteristics that the first edge covering mechanism comprises a first edge covering unit, a first edge covering driving component and a first edge covering block, the first edge covering driving component and the first edge covering block are correspondingly arranged at the outer side of the transition edge, are horizontally arranged, are inverted L-shaped, are matched with the shape of the transition edge, and have a first upper surface which is S-shaped in the vertical direction; the first positioning pressing unit comprises a first pressing driving component and a first pressing block and is rotatably connected to the first flanging block; the first control unit controls the first pressing driving component to drive the first pressing block to rotate forwards by a preset angle, so that the lower pressing surface presses the surface skin on the first upper surface in a preset state, and the preset state is a state that the first pressing block and the first flanging block can drive the surface skin to move and can slide relative to the surface skin.

Description

Edge covering mechanism capable of imitating hand-shaped grabbing

Technical Field

The utility model relates to a machinery, concretely relates to mechanism of borduring that imitative hand form snatched.

Background

In the processing process of the semi-finished automobile handrail, hot melt adhesive is sprayed on the inner surface of the cut surface skin to form a hot melt adhesive layer, then the surface skin with the hot melt adhesive layer is adhered on the outer surface of the automobile handrail framework, and the surface skin positioned at the edge of the automobile handrail framework is turned over and coated and adhered on the inner surface of the automobile handrail framework.

At present, the glue spraying process in the processing of semi-finished automobile products is generally completed manually, and the processes of pasting skins, decorating fabrics and the like and edge covering are completed through manual or automatic edge covering equipment. CN108582808A discloses a door panel edge covering device with a pulling member, which is used for adhering decorative fabric to a door panel frame and performing edge covering processing, wherein a fabric fixing structure used when adhering the fabric is fixed in a pulling and vacuumizing manner by the pulling member, the setting of the pulling member occupies a larger space, which is not beneficial to the layout of the whole device, and the control process of the pulling member is also complicated.

In addition, the structure of the automobile handrail is greatly different from that of an automobile door panel, and the edge covering requirement is also different. Fig. 8 is a schematic structural diagram of the armrest frame of the present invention, and as shown in fig. 8, the armrest frame 1 includes a transition edge 2 and a non-transition edge 3. Fig. 9 is an enlarged schematic view of the transition side in fig. 8, and as shown in fig. 9, the transition side 2 is narrowed in the horizontal direction by a width and gradually lowered in the vertical direction by a height, i.e., it is S-shaped in both the horizontal direction and the vertical direction. The special structure of the transition edge 2 increases the edge covering difficulty of the part, and the edge covering structure in the prior art cannot be used for edge covering.

In addition, the surface skin for processing the automobile handrail is a PVC surface skin and comprises a first surface skin area and a second surface skin area which are connected together, three suture lines extending along the length direction are arranged on the first surface skin area for the sake of attractiveness, a plurality of positioning holes are cut in advance on the whole edge of the whole surface skin, the positioning holes penetrate through the surface skin, and the positioning holes are uniformly distributed along the edge of the surface skin. In the prior art, there is no special fixture for positioning such a skin.

In summary, it is highly desirable to provide an automatic apparatus for surface coating, fixing and edge covering of an automobile handrail.

SUMMERY OF THE UTILITY MODEL

The utility model relates to a solve above-mentioned car handrail skeleton's transition limit problem of borduring and go on, aim at provides an imitative hand form mechanism of borduring who snatchs.

The utility model provides a mechanism of borduring that imitative hand form snatched for to overturn the epidermis that will glue on the transition limit of car handrail skeleton to the internal surface from the surface of car handrail skeleton, the transition limit all is S-shaped on horizontal direction and vertical direction, has such characteristic, include: first turn-ups unit, first location compress tightly unit and first the control unit, and first turn-ups unit includes: the first flanging block is correspondingly arranged at the outer side of the transition edge, is horizontally arranged, is in an inverted L shape, is matched with the shape of the transition edge, and is provided with a first upper surface and a first lower surface which are in an S shape in the vertical direction and a first side surface which is in an S shape in the horizontal direction; and a first flanging driving member for driving the first flanging block to advance or retreat, the first positioning pressing unit comprises: the first pressing block is rotatably connected to the first flanging block, is in an inverted L shape, and is provided with a pressing lower surface matched with the shape and size of the first upper surface; the first control unit controls the first pressing driving component to drive the first pressing block to rotate forwards by a preset angle, so that the pressing lower surface presses the skin on the first upper surface in a preset state, and the preset state is a state that the first pressing block and the first flanging block can drive the skin to move and can slide relative to the skin; the first control unit also controls the first flanging driving component to drive the first flanging block to move forwards at a second preset speed, so that the surface skin is overturned from the outer surface to the inner surface of the automobile armrest framework.

The utility model provides an among the mechanism of borduring that imitative hand form snatched, can also have such characteristic: the first flanging driving component is further used for driving the first flanging block to move downwards or ascend, the first control unit further controls the first flanging driving component to drive the first flanging block to ascend at a first preset speed, so that the first lower surface is higher than the upper surface of the transition edge by a preset height, and the first control unit further controls the first flanging driving component to drive the first flanging block to move downwards at a third preset speed, so that the surface skin covers the inner surface of the automobile handrail framework.

The utility model provides an among the mechanism of borduring that imitative hand form snatched, can also have such characteristic: wherein the first predetermined speed, the second predetermined speed, and the third predetermined speed are equal.

The utility model provides an among the mechanism of borduring that imitative hand form snatched, can also have such characteristic: wherein the predetermined height is less than or equal to the thickness of the skin.

The utility model provides an among the mechanism of borduring that imitative hand form snatched, can also have such characteristic: the first upper surface, the first lower surface, the first side surface and the pressing lower surface are smooth surfaces.

The utility model provides an among the mechanism of borduring that imitative hand form snatched, can also have such characteristic: wherein, first compact heap and first turn-ups piece are connected through the pivot is rotatable.

The utility model provides an among the mechanism of borduring that imitative hand form snatched, can also have such characteristic: wherein, first compress tightly drive component and first turn-ups drive component are cylinder drive component.

Action and effect of the utility model

According to the utility model, the utility model relates to a hand-shaped grabbing edge covering mechanism, because the mechanism comprises a flanging unit, a positioning pressing unit and a first control unit, the flanging unit comprises a pressing block and a pressing driving component, the positioning pressing unit comprises a pressing block and a pressing driving component, the first control unit can control the pressing driving component to drive the pressing block to rotate forward by a preset angle, so that the lower pressing surface presses the surface skin on the first upper surface in a preset state, the preset state is a state that the pressing block and the flanging block can drive the surface skin to move and can slide relative to the surface skin, therefore, when the flanging block moves forward at a second preset speed under the control of the first control unit, the surface skin is enabled to overturn from the outer surface to the inner surface of the automobile handrail framework, the state that the surface skin is tensioned and slowly slides out while the edge covering is manually simulated, and the surface skin wrinkles are prevented, the high-quality edge covering of the transition edge of the framework is realized.

Drawings

Fig. 1 is a block diagram of an embodiment of the present invention, which illustrates a system for spraying glue and covering edges of an automobile armrest;

fig. 2 is a schematic perspective view of a composite edge covering device for an automobile handrail according to an embodiment of the present invention;

fig. 3 is a schematic perspective view of the composite hemming device for the automobile armrest in the embodiment of the present invention;

fig. 4 is a schematic structural view of a skin fixing device according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a pneumatic positioning unit in an embodiment of the present invention;

fig. 6 is a schematic structural view of a hemming device in an embodiment of the present invention;

fig. 7 is a schematic structural view of a hemming mechanism for imitating hand-shaped grabbing in the embodiment of the present invention;

fig. 8 is a schematic structural view of the armrest frame of the present invention;

fig. 9 is an enlarged schematic view of the transition edge of fig. 8.

Detailed Description

In order to make the utility model realize that the technical means, the creation characteristics, the achievement purpose and the efficiency are easy to understand and understand, the following embodiment combines the accompanying drawings to be right the utility model discloses the mechanism of borduring that imitative hand form snatched does specifically expoundly.

Fig. 1 is a block diagram of an embodiment of the present invention, which illustrates a system for spraying glue and covering edges of an automobile armrest.

As shown in the figure, the present embodiment provides an automobile handrail glue spraying and edge covering system 1000, which includes a glue spraying device 100, an automobile handrail composite edge covering device 200, and a control device 300. The control device 300 is used for controlling the operations of the glue spraying device 100 and the automobile handrail composite hemming device 200, so that the processed skin of the glue spraying device 100 is transferred to the automobile handrail composite hemming device 200 for processing at constant intervals. The transfer can be manual or automatic.

The glue spraying apparatus 100 is used for spraying hot melt glue on the inner surface of the cut skin mentioned in the background art, and has a glue spraying control device 110. The glue spraying device 100 is a prior art, for example, the glue spraying device is applied to an automotive interior door panel in the previously published chinese utility model patent application CN110947561A applied by the applicant, and on this basis, a bracket of a placing part for fixing the automotive interior door panel is changed into a structure for fixing a skin. In addition, the glue spraying control device 110 is in communication connection with the control device 300 and operates under the control of the control device 300.

Fig. 2 is a schematic perspective view of a composite edge covering device for an automobile handrail according to an embodiment of the present invention; fig. 3 is a schematic perspective view of a composite edge covering device for an automobile armrest in an embodiment of the present invention.

The automobile handrail composite edge covering device 200 is used for adhering the surface skin with the hot melt adhesive (layer) on the inner surface processed by the glue spraying device 100 to the automobile handrail framework 1 and covering the edge of the automobile handrail framework 1. As shown in fig. 1 to 3, the composite hemming apparatus 200 for an automobile armrest includes a supporting mechanism 210, a skin fixing device 220, a frame fixing device 230, a baking device 240, a hemming device 250, and a hemming control device 260.

The hemming control device 260 is communicatively connected to the control apparatus 300, and includes a first control portion 261 and a second control portion 262. The first control part 261 is used to control the operations of the skin fixing device 220, the skeleton fixing device 230, and the baking device 240 under the control of the control apparatus 300. The second control part 262 is used to control the operation of the hemming device under the control of the control apparatus 300.

As shown in fig. 2 and 3, the support mechanism 210 includes a lower support 211 and an upper support 212 connected together.

Fig. 4 is a schematic structural view of the skin fixing device according to an embodiment of the present invention.

As shown in fig. 4, the skin fixing device 220 is used for fixing and positioning the skin, and includes a fixing frame (not shown), a profiling mold 221, a pneumatic positioning unit 222, and a vacuum generator 223 (not shown). The fixing frame is mounted on the lower support 211.

The profiling mold 221 is fixedly arranged on the fixing frame, has a shape matched with that of the automobile handrail framework 1, and is used for fixing the surface skin in the processing process, preventing the surface skin from moving in the processing process and facilitating the smooth processing process. The profiling mold 221 includes a first mold region 2211, a second mold region 2212, and a long side region 2213. First and second tread regions 2211 and 2212 are provided with a plurality of through hole groups 2214, each through hole group 2214 comprising 4-8 through holes 22141 arranged in a straight line.

The first molding region 2211 corresponds to the first skin region of the skin, and the plurality of through holes 22141 in the through hole groups 2214 provided in the first molding region 2211 are linearly distributed along the longitudinal direction of the copying mold 221, and the plurality of through hole groups 2214 are distributed in rows and columns. The portions of first mold area 2211 corresponding to the stitches of the skin are not provided with through holes 22141. The second molding region 2212 corresponds to the second skin region of the skin, and the plurality of through holes 22141 in the through hole groups 2214 provided in the second molding region 2212 are linearly distributed along the length direction of the copying mold 221, and the plurality of through hole groups 2214 are distributed in rows. The long side area 2213 is provided with a plurality of through holes 2215 uniformly distributed along the longitudinal direction thereof.

The vacuum generator is fixedly disposed on the fixing frame and is a vacuum pump, and the vacuum pump is respectively communicated with the through holes 22141 through vacuum pipes (not shown in the figure). When the vacuum pump evacuates the vacuum line and air in the through hole 22141, the through hole 22141 draws the skin tightly against the copying form 221.

Fig. 5 is a schematic structural diagram of a pneumatic positioning unit in an embodiment of the present invention.

As shown in fig. 5, the pneumatic positioning unit 222 is fixedly disposed on the fixing frame, and has a positioning pin 2221 and a positioning pin driving cylinder 2222. The locating pins 2221 are fitted into the locating holes of the skin for passing through the locating holes so that the skin is located on the profiling mold 221. The stylus driving cylinder 2222 is used to drive the stylus 2221 to move down or up. After the positioning needle driving cylinder 2222 drives the positioning needle 2221 to rise, the positioning needle 2221 is at the positioning station, and at this time, the skin can be positioned on the profiling mold 221 by placing the skin on the positioning needle, so that the first skin region of the skin corresponds to the first mold region 2211, and the second skin region corresponds to the second mold region 2212. After the positioning needle driving cylinder 2222 drives the positioning needle 2221 to move downwards, the hemming device 250 can conveniently hem from the upper part of the positioning needle 2221.

The number of pneumatic positioning units 222 is the same as the number of positioning holes on the skin. The plurality of pneumatic positioning units 222 are arranged around the periphery of the profiling mold 221 in a surrounding manner, and the distribution of the pneumatic positioning units corresponds to the distribution of the positioning holes.

The pneumatic positioning unit 222 corresponding to the long side area 2213 is arranged below the through hole 2215 of the long side area 2213, when the positioning needle driving cylinder 2222 drives the positioning needles 2221 to ascend, the positioning needles 2221 penetrate through the through holes 2215 to reach the positioning stations, and the parts of the positioning needles 2221 penetrating through the through holes 2215 are used for positioning the skin. When the positioning needle driving cylinder 2222 drives the positioning needle 2221 to move downwards, the top of the positioning needle 2221 is lower than the top of the through hole 2215.

As shown in fig. 2, the frame fixing device 230 is mounted on the upper support portion 212, and is used for fixing the armrest frame 1 of the vehicle, and includes a frame fixing unit (not shown) and a vertical driving unit (not shown). The framework fixing unit is installed on the vertical driving unit, is positioned right above the profiling mold 221, and is used for fixing the automobile handrail framework 1 and moving up and down under the driving of the vertical driving unit. The framework fixing unit is in the prior art, for example, a structure that a positioning mould and a clamping jaw are matched is adopted. Vertical drive units are known in the art, for example, in a slide rail type configuration.

As shown in fig. 3, a baking device 240 is installed on the lower support 211 for heating the hot melt adhesive on the armrest frame 1 and the skin of the automobile. The roasting apparatus 240 includes a heating unit 241 and a horizontal driving unit (not shown in the drawings). The heating unit 241 includes a heating frame (not shown), an upper heating pipe (not shown), and a lower heating pipe (not shown). The heating rack is installed on the horizontal driving unit. The upper heating pipe is arranged on the heating frame and used for heating the automobile handrail framework 1 under the control of the first control part 261; the lower heating pipe is installed on the heating rack and is used for melting the hot melt adhesive layer of the skin under the control of the first control part 261. The horizontal driving unit is used for driving the heating rack of the heating unit 241 to move horizontally. When the heating frame is driven by the horizontal driving unit and moves horizontally from the heating initial position to the heating position, the upper heating pipe is located below the framework fixing unit and corresponds to the framework fixing unit, and the lower heating pipe is located above the profiling mold 221 and corresponds to the profiling mold 221. Horizontal drive units are known in the art, for example, in a slide rail type configuration.

Fig. 6 is a schematic structural diagram of the edge covering device in the embodiment of the present invention.

As shown in fig. 6, the hemming device 250 is used to turn the skin adhered to the armrest frame 1 from the outer surface to the inner surface of the armrest frame 1, and includes a hemming mechanism 251 for imitating a hand grip and a non-transitional hemming mechanism 252. Both the edge covering mechanism 251 for imitating the hand-shaped grabbing and the non-transitional edge covering mechanism 252 are arranged on the outer side of the copying mold 221.

Fig. 7 is a schematic structural diagram of the edge covering mechanism for imitating the hand-shaped grabbing in the embodiment of the present invention.

As shown in fig. 7, a wrapping mechanism 251 for imitating a hand grip is used for wrapping the transition edge 2 of the armrest frame 1 of the vehicle, and therefore, this mechanism is also called a transition edge wrapping mechanism. The number of the transition edge covering mechanisms 251 is at least 2, and the transition edge covering mechanisms are respectively arranged at positions corresponding to the transition edges 2. Each of the hemming and edge covering mechanisms 251 includes a first hemming unit 2511, a first positioning and pressing unit 2512, and a first control unit (not shown),

the first burring unit 2511 includes a first burring block 25111 and a first burring drive member 25112. The first flanging block 25111 is disposed outside the transition edge 2, is horizontally disposed, has an inverted L shape, matches the shape of the transition edge, and has a first upper surface 251111 and a first lower surface 251112 which are S-shaped in the vertical direction, and a first side surface 251113 which is S-shaped in the horizontal direction. The first burring drive member 25112 is used for driving the first burring block 25111 to perform forward or backward or downward or upward movement. The first burring drive member 25112 is a cylinder drive member including, for example, two cylinders that drive the movement of the first burring block 25111 in the horizontal direction and the vertical direction, respectively.

The first positioning and pressing unit 2512 includes a first pressing block 25121 and a first pressing drive member 25122. The first pressing block 25121 is rotatably connected to the first flanging block 25111 through a rotating shaft, so that the first pressing block 25121 can rotate relative to the first flanging block 25111 and can move forward or backward or move downward or ascend together with the first flanging block 25111. First compression block 25121 is an inverted L-shape with a compression lower surface 251211 that matches the shape and size of first upper surface 251111. And a first pressing driving member 25122 for driving the first pressing block to rotate forward or backward by a predetermined angle. The first pressing drive member 25122 is a cylinder drive member.

The first upper surface 251111, the first lower surface 251112, the first side surface 251113, and the compacting lower surface 251211 are smooth surfaces.

The first control unit is communicatively connected to the second control portion 262, and is configured to control the first pressing drive member 25122 to drive the first pressing block 25121 to rotate forward or backward by a predetermined angle under the control of the second control portion 262. When the first pressing block 25121 is rotated forward by a predetermined angle, the pressing lower surface 251211 presses the skin against the first upper surface 251111 in a predetermined state. The predetermined state is a state in which the first pressing block 25121 and the first flanging block 25111 can both drive the skin to move and slide relative to the skin.

The first control unit is also used for controlling the first flanging driving member 25112 to drive the first flanging block 25111 to move forward or backward or move up or down under the control of the second control part 262. When the first flanging block 25111 moves forwards, the first flanging block 25111 turns the skin from the outer surface to the inner surface of the automobile armrest framework 1; when the first flanging block 25111 moves downwards, the first flanging block 25111 enables the surface skin to cover the inner surface of the automobile armrest framework 1.

As shown in fig. 6, the non-transition edge hemming mechanism 252 is used to hem the non-transition edge 3 of the armrest frame 1 of the vehicle. The number of the non-transition edge covering mechanisms 252 is plural, and the non-transition edge covering mechanisms are respectively arranged at positions corresponding to the non-transition edges 3. Each non-transitional edge binding mechanism 252 includes a second flanging unit 2521 and a first control unit (not shown).

The second burring unit 2521 includes a second burring block 25211 and a second burring drive member 25212. The second flanging block 25211 is matched with the shape of the non-transition edge and is in an inverted L shape. The second flanging driving member 25212 is used for driving the second flanging block 25211 to move forward or backward or move up or down. The second burring drive member 25212 is a cylinder drive member.

The second control unit is communicatively connected to the second control portion 262, and is configured to control the second flanging driving member 25212 to drive the second flanging block 25211 to move forward or backward or upward or downward under the control of the second control portion 262. When the second flanging block 25211 performs forward motion, the second flanging block 25211 turns the skin from the outer surface to the inner surface of the automobile armrest framework 1; when the second flanging block 25211 moves downwards, the second flanging block 25211 makes the skin cover the inner surface of the armrest framework 1.

The process of the first control part 261 controlling the operations of the skin fixing device 220, the frame fixing device 230 and the baking device 240 under the control of the control apparatus 300 so as to adhere the skin having a hot melt adhesive (layer) on the inner surface thereof to the armrest frame 1 of the automobile includes the steps of:

in step S1-1, the first control unit 261 controls the stylus driving cylinder 2222 to drive the stylus 2221 from its initial position to the positioning position, and then proceeds to step S1-2.

Step S1-2, aligning the positioning holes of the skin with the positioning pins 2221, and placing the skin on the profiling mold 221 and the positioning pins 2221 in a back-up state. The armrest frame 1 is fixed to the frame fixing unit in a state in which the surface (outer surface) to which the skin is to be attached faces downward. And then proceeds to step S1-3.

In step S1-3, the first control unit 261 controls the vacuum generator to vacuumize, and adsorbs the decorative fabric onto the copying mold 221. And then proceeds to step S1-4.

In step S1-4, the first control unit 261 controls the vertical driving unit to drive the frame fixing unit to move down from its initial position to the position to be heated, and controls the horizontal driving unit to drive the heating unit 241 to move horizontally from the initial heating position to the heating position. And then proceeds to step S1-5.

In step S1-5, the first control unit 261 controls the upper heating pipe to heat the armrest skeleton 1 of the vehicle, and controls the lower heating pipe to heat the hot melt adhesive layer of the skin fixed to the profiling mold 221. And then proceeds to step S1-6.

In step S1-6, the first control part 261 controls the horizontal driving unit to drive the heating unit 241 to retreat to the heating initial position, and controls the upper-heater duct and the lower-heater duct to stop heating. And then proceeds to step S1-7.

In step S1-7, the first control unit 261 controls the vertical driving unit to drive the frame fixing unit to move down from the station to be heated to the pasting station, so that the armrest frame 1 is pressed against the skin. And then proceeds to step S1-8.

In step S1-8, the first control unit 261 controls the stylus driving cylinder 2222 to drive the stylus 2221 from its positioning position to its initial position. At this time, the hemming device 250 operates to turn and press the skin located at the edge of the handle frame 1 to the inner surface of the handle frame 1. And then proceeds to step S1-9.

In step S1-9, the first control unit 261 controls the vacuum generator to stop vacuum-pumping, and then proceeds to step S1-10.

In step S1-10, the first control part 261 controls the vertical driving unit to drive the frame fixing unit to ascend from the pasting station to the initial station thereof, and then proceeds to step S1-11.

And step S1-11, taking down the automobile armrest framework 1 which is pasted and edge-covered (processed) from the framework fixing unit, and finishing one-round pasting and edge-covering processing.

The process that the second control part 262 controls the transition edge covering mechanism 251 to cover the transition edge 2 of the automobile armrest framework 1 through the first control unit under the control of the control device 300 comprises the following steps:

in step S2-1, the first control unit controls the first pressing drive member 25122 to drive the first pressing block 25121 to rotate forward by a predetermined angle so that the pressing lower surface 251211 presses the skin against the first upper surface 251111 in a predetermined state, and then proceeds to step S2-2. The predetermined state is a state in which the first pressing block 25121 and the first flanging block 25111 can both drive the skin to move and slide relative to the skin.

In step S2-2, the first control unit controls the first burring drive member 25122 to drive the first burring block 25111 to perform an ascending motion at a first predetermined speed from the initial position to the first burring position, and then proceeds to step S2-3. When the first cuff block 25111 is in the first cuff position, the first lower surface 251112 is a predetermined height above the upper surface of the transition edge 2 that is less than or equal to the thickness of the skin.

In step S2-3, the first control unit controls the first burring drive member 25122 to drive the first burring block 25111 to advance from the first burring position to the second burring position at a second predetermined speed, such that the skin is turned over from the outer surface to the inner surface of the armrest frame 1, and then proceeds to step S2-4.

In step S2-4, the first control unit controls the first burring drive member 25122 to drive the first burring block 25111 to move down from the second burring position at a third predetermined speed such that the skin covers the inner surface of the armrest frame, and then proceeds to step S2-5.

Wherein, in steps S2-S4, the first control unit further controls the first pressing block 25121 to be maintained in a state such that the skin is pressed against the first upper surface 251111 in a predetermined state. The first predetermined speed, the second predetermined speed, and the third predetermined speed are equal.

In step S2-5, the first control unit controls the first burring drive member 25122 to drive the first burring block 25111 to return to the initial position through ascending, retreating, and downward movements in sequence. The return speed of the first tuck flap 25111 is greater than or equal to a first predetermined speed, and preferably greater than the first predetermined speed.

The process that the second control part 262 controls the non-transition edge covering mechanism 252 to cover the non-transition edge 3 of the automobile armrest framework 1 through the second control unit under the control of the control device 300 comprises the following steps:

in step S3-1, the second control unit controls the second burring drive member 25212 to drive the second burring block 25211 to perform a forward movement from its initial position so that the skin is turned over from the outer surface to the inner surface of the vehicle armrest frame 1, and then proceeds to step S3-2.

In step S3-2, the second control unit controls the second burring drive member 25212 to drive the second burring block 25211 to move down so that the skin covers the inner surface of the vehicle armrest frame, and then proceeds to step S3-3.

In step S3-3, the second control unit controls the second burring drive member 25212 to drive the second burring block 25211 to return to its initial position through ascending and retreating motions in sequence.

Effects and effects of the embodiments

According to the hand-shaped grabbing edge covering mechanism of the embodiment, the edge covering mechanism comprises an edge covering unit, a positioning pressing unit and a first control unit, the edge covering unit comprises a pressing block and a pressing driving member, the positioning pressing unit comprises a pressing block and a pressing driving member, the first control unit can control the pressing driving member to drive the pressing block to rotate forwards by a preset angle, so that the lower pressing surface presses the surface skin onto the first upper surface in a preset state, the preset state is a state that the pressing block and the edge covering block can drive the surface skin to move and can slide relative to the surface skin, therefore, when the edge covering block moves forwards at a second preset speed under the control of the first control unit, the surface skin is enabled to be turned over from the outer surface to the inner surface of the automobile handrail framework, the state that the surface skin is tensioned and slowly slides out while edge covering during artificial edge covering is simulated, and the surface skin wrinkles are prevented, the high-quality edge covering of the transition edge of the framework is realized.

Similarly, when the flanging block performs the ascending action at the first preset speed and performs the descending action at the third preset speed under the control of the first control unit, the skin is in a tight and slowly sliding-out state.

Further, the first control unit also controls the flanging driving component to drive the flanging block to ascend at a first preset speed, so that the first lower surface is higher than the preset height of the upper surface of the transition edge, the preset height is smaller than or equal to the thickness of the skin, and when the skin is turned over from the outer surface to the inner surface of the automobile handrail framework, the flanging block presses the skin on the automobile handrail framework, and therefore a better pasting edge covering effect is achieved.

Furthermore, the first preset speed, the second preset speed and the third preset speed are equal and are smaller than the returning speed of the flanging block, so that the uniformity during flanging is ensured, a good flanging effect is realized, the returning time is further shortened, and the processing efficiency is improved.

Furthermore, the pressing block and the flanging block are rotatably connected through the rotating shaft, the structure is simple, and the flanging block can be conveniently controlled to rotate by a preset angle.

The above embodiments are preferred examples of the present invention, and are not intended to limit the scope of the present invention.

Claims (7)

1. The utility model provides an imitative hand form mechanism of borduring who snatchs for will glue the epidermis on the transition limit of car handrail skeleton and follow the surface upset to the internal surface of car handrail skeleton, the transition limit all is S-shaped on horizontal direction and vertical direction, its characterized in that includes:

a first flanging unit, a first positioning and pressing unit and a first control unit,

the first burring unit includes:

the first flanging block is correspondingly arranged at the outer side of the transition edge, is horizontally arranged, is in an inverted L shape, is matched with the transition edge in shape, and is provided with a first upper surface and a first lower surface which are in an S shape in the vertical direction and a first side surface which is in an S shape in the horizontal direction; and

a first flanging driving component for driving the first flanging block to move forwards or backwards,

the first positioning and pressing unit includes:

the first pressing block is rotatably connected to the first flanging block, is in an inverted L shape, and is provided with a pressing lower surface matched with the shape and size of the first upper surface; and

a first pressing driving member for driving the first pressing block to rotate forward or backward by a predetermined angle,

the first control unit controls the first pressing driving component to drive the first pressing block to rotate forwards by the preset angle, so that the lower pressing surface presses the skin on the first upper surface in a preset state, wherein the preset state is a state that the first pressing block and the first flanging block can both drive the skin to move and can also slide relative to the skin;

the first control unit further controls the first flanging driving component to drive the first flanging block to perform forward motion at a second preset speed, so that the surface skin is overturned from the outer surface to the inner surface of the automobile armrest framework.

2. The hand-shaped grabbing edge covering mechanism according to claim 1 is characterized in that:

wherein the first flanging driving component is also used for driving the first flanging block to move downwards or upwards,

the first control unit also controls the first flanging driving member to drive the first flanging block to perform ascending action at a first preset speed, so that the first lower surface is higher than the upper surface of the transition edge by a preset height,

the first control unit further controls the first flanging driving component to drive the first flanging block to move downwards at a third preset speed, so that the surface skin covers the inner surface of the automobile armrest framework.

3. The hand-shaped grabbing imitated edge covering mechanism according to claim 2, is characterized in that:

wherein the first predetermined speed, the second predetermined speed, and the third predetermined speed are equal.

4. The hand-shaped grabbing imitated edge covering mechanism according to claim 2, is characterized in that:

wherein the predetermined height is less than or equal to a thickness of the skin.

5. The hand-shaped grabbing edge covering mechanism according to claim 1 is characterized in that:

wherein the first upper surface, the first lower surface, the first side surface, and the compacting lower surface are smooth surfaces.

6. The hand-shaped grabbing edge covering mechanism according to claim 1 is characterized in that:

the first pressing block and the first flanging block are rotatably connected through a rotating shaft.

7. The hand-shaped grabbing edge covering mechanism according to claim 1 is characterized in that:

the first pressing driving component and the first flanging driving component are cylinder driving components.

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