CN114505903A - Vertical cutting and processing device for processing automotive interior parts - Google Patents

Abstract

The invention belongs to the technical field of automobile part processing, and discloses a vertical cutting processing device for processing an automobile interior part, which comprises: the automatic feeding mechanism comprises a plurality of conveying rollers capable of synchronously rotating in the same direction, and the plurality of conveying rollers comprise a driving roller; the cutter assembly is arranged above the automatic feeding mechanism; the cutter assembly is used for lifting and descending, the automatic feeding mechanism is driven to convey by the linkage mechanism at regular time, one-time descending and one-time lifting of the cutter assembly are combined into one moving stroke, and the linkage mechanism is also used for changing the conveying distance of the automatic feeding mechanism in one moving stroke; in conclusion, the linkage mechanism is utilized to enable the integral vertical cutting and machining device to be only provided with one driving device, the double driving of cutting and feeding can be realized by utilizing one driving device, the energy consumption is reduced, and the machining cost is reduced.

Description

Vertical cutting and processing device for processing automotive interior parts

Technical Field

The invention belongs to the technical field of automobile part machining, and particularly relates to a vertical cutting machining device for machining an automobile interior part.

Background

Automotive interior relates to a plurality of parts or workpieces which are mainly formed by combining an engineering plastic part and a surface layer patch. At present, when the automotive interior part is processed, corresponding cutting operation is required to be carried out on the corresponding engineering plastic part and the surface layer cloth, and for different parts, the cutting length and the cutting position are different, so that flexible feeding is required to be effectively realized in the cutting process.

In the existing cutting process, two modes of manual feeding and automatic feeding are mainly included; wherein: for manual feeding, the feeding length is convenient to control, but the control precision is poor and the processing efficiency is low; for automatic feeding, feeding is accurate and efficient, but the feeding length is inconvenient to flexibly adjust, an additional feeding driving part needs to be arranged, and the processing cost is high.

Disclosure of Invention

In view of the above, the present invention is directed to a vertical cutting device for machining an interior part of an automobile.

In order to achieve the purpose, the invention provides the following technical scheme: a vertical cutting processing device for processing an automobile interior part, comprising:

the automatic feeding mechanism comprises a plurality of conveying rollers capable of synchronously rotating in the same direction, and the plurality of conveying rollers comprise a driving roller;

the cutter component is arranged above the automatic feeding mechanism;

the automatic feeding mechanism is driven to convey by the cutter component through the linkage mechanism at regular time in the lifting process, one-time descending and one-time rising of the cutter component are combined into one moving stroke, and the linkage mechanism is further used for changing the conveying distance of the automatic feeding mechanism in one moving stroke.

Preferably, the linkage mechanism includes:

the rotatable eccentric roller drives the cutter assembly to lift through the rotation of the eccentric roller;

the transmission component is used for realizing linkage between the rotation of the eccentric roller and the transmission of the automatic feeding mechanism;

the connecting assembly is matched between the eccentric roller and the transmission assembly and is used for realizing the timing connection of the eccentric roller and the transmission assembly.

Preferably, the connection assembly includes:

the driving gear is an incomplete gear with an opening formed in one side, and the driving gear and the eccentric roller are coaxially mounted;

the driven gear can be meshed with the driving gear, is a complete gear and is used for driving the transmission assembly to transmit; when the driving gear rotates to the middle position of the opening and corresponds to the driven gear, the cutter assembly descends to the lowest position.

Preferably, the transmission assembly comprises:

one of the rotating pieces is coaxially mounted with the driving roller, and the other rotating piece is coaxially mounted with the driven gear;

and the linkage belt is sleeved on the two rotating pieces and is conveyed along with the rotation of the rotating pieces.

Preferably, the rotating member includes:

a rotating shaft;

the N driving rollers are arranged around the rotating shaft in an array mode and meshed with the linkage belt;

and a telescopic member connected between each of the driving rollers and the rotating shaft.

Preferably, the cutter assembly comprises:

a lifting plate;

the cutting knife and the elastic pressing piece are arranged at the bottom of the lifting plate, and when the elastic pressing piece is not compressed, the length of the elastic pressing piece is not less than that of the cutting knife.

Preferably, the elastic pressing piece comprises an elastic telescopic rod and a pressing plate connected to the bottom of the elastic telescopic rod.

Preferably, the elastic telescopic rod comprises:

an outer rod;

the inner rod, and one end of the said inner rod stretches into the inside of the outer pole;

the material pressing spring is connected between the inner rod and the outer rod and is always limited in the outer rod.

Preferably, a portal frame is fixed at the top of the automatic feeding mechanism, the cutter assembly is mounted inside the portal frame, and a limiting spring is connected between the top of the lifting plate and the top of the portal frame.

Preferably, the automatic feeding mechanism is provided with a cutting cavity positioned between the adjacent conveying rollers, and the cutting cavity is positioned under the cutting knife.

Compared with the prior art, the invention has the following beneficial effects:

(1) the automatic feeding mechanism adopts automatic feeding, and a variable-speed linkage mechanism is arranged between the automatic feeding mechanism and the cutter assembly, and the cutter assembly can drive the automatic feeding mechanism to convey at regular time through the linkage mechanism in the lifting process, so that double driving of cutting and feeding can be realized by using one driving device, the energy consumption is reduced, and the processing cost is reduced; in addition, the linkage mechanism can also effectively change the drive ratio between the automatic feeding mechanism and the cutter assembly through variable speed adjustment, so that feeding with different lengths can be flexibly realized, and the linkage mechanism is further effectively suitable for cutting processing of different parts.

(2) To above-mentioned link gear, including rotatable eccentric roller, and the rotation through eccentric roller orders about the cutter unit spare and goes up and down, effectively realizes the switching between lifting drive and the rotation drive from this, and then conveniently realizes the accurate linkage between autoloading mechanism and the cutter unit spare.

(3) Aiming at the linkage mechanism, the stepless speed change mechanism also comprises a transmission assembly consisting of two rotating pieces and a linkage belt, and the rotating diameter of the rotating pieces is variable, so that the stepless speed change adjustment of the whole linkage mechanism can be flexibly realized, and the stepless speed change mechanism is simple in structure and convenient to adjust.

(4) Aiming at the linkage mechanism, a connecting component consisting of a driving gear and a driven gear is further arranged between the eccentric roller and the transmission component, wherein the driving gear is an incomplete gear with an opening formed in one side, and therefore mutual interference between the cutter component and the automatic feeding mechanism is effectively avoided when cutting is executed.

(5) Aiming at the cutter component, the elastic pressing piece corresponding to the cutter is arranged, so that the stability of workpiece positioning during cutting is effectively ensured, and the feeding of the workpiece is not interfered.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a side view taken along direction A of FIG. 1;

FIG. 3 is a side view taken along direction B of FIG. 1;

FIG. 4 is a schematic view of the internal structure of the present invention;

FIG. 5 is a schematic view of a rotary member according to the present invention;

FIG. 6 is a schematic view of the structure of the eccentric roller, the driving gear and the driven gear of the present invention;

FIG. 7 is a schematic view of the structure of the elastic telescopic rod of the present invention;

FIGS. 8-10 are cutting schematics of the present invention;

in the figure: an automatic feeding mechanism-1; a cutter assembly-2; a lifting plate-21; a cutter-22; an elastic pressing member-23; a limiting spring-24; an elastic telescopic rod-25; a pressure plate-26; an outer rod-27; an inner rod-28; a material pressing spring-29; an eccentric roller-3; a transmission assembly-4; a rotating member-41; linkage belt-42; a rotation axis-43; a driving roller-44; -45, a telescoping piece; a driving gear-5; a driven gear-6; a portal frame-7.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1 to 10, the present invention provides a vertical cutting device for processing an interior part of an automobile, and the vertical cutting device mainly includes the following structure:

the automatic feeding mechanism 1 comprises a plurality of conveying rollers capable of synchronously rotating in the same direction, and the plurality of conveying rollers comprise a driving roller;

the cutter component 2 can lift, and the cutter component 2 is arranged above the automatic feeding mechanism 1;

the automatic feeding mechanism comprises a variable-speed linkage mechanism, the cutter component 2 drives the automatic feeding mechanism 1 to convey at regular time through the linkage mechanism in the lifting process, one-time descending and one-time rising of the cutter component 2 are combined into one moving stroke, and the linkage mechanism is also used for changing the conveying distance of the automatic feeding mechanism 1 in one moving stroke.

Above-mentioned, utilize link gear's setting to make whole vertical cutting processingequipment only need set up a drive arrangement to utilize a drive arrangement can effectively realize the dual drive of cutting and feeding.

Specifically, with respect to the above disclosed structure, a preferred embodiment of the linkage mechanism is provided in the present invention; the link gear includes:

the rotatable eccentric roller 3 drives the cutter assembly 2 to lift through the rotation of the eccentric roller 3;

the transmission component 4 is variable in speed, and the transmission component 4 is used for realizing linkage between the rotation of the eccentric roller 3 and the transmission of the automatic feeding mechanism 1;

the driving gear 5 is an incomplete gear with an opening at one side, and the driving gear 5 and the eccentric roller 3 are coaxially arranged;

the driven gear 6 can be meshed with the driving gear 5, the driven gear 6 is a complete gear, and the driven gear 6 is used for driving the transmission assembly 4 to transmit.

Above-mentioned, driving gear 5 and driven gear 6 constitute the coupling assembling between eccentric roller 3 and the drive assembly 4, and when driving gear 5 rotated to open-ended intermediate position and driven gear 6 corresponding, cutter unit 2 descends to the lowest position, effectively guarantees not to produce mutual interference between cutter unit 2 and autoloading mechanism 1 when carrying out the cutting from this.

Above-mentioned, transmission assembly 4 includes two rotating members 41 and the linkage belt 42 of cover locating on two rotating members 41, and one of them rotating member 41 and drive roll coaxial arrangement, another rotating member 41 and driven gear 6 coaxial arrangement, and rotating member 41 includes:

a rotating shaft 43;

n driving rollers 44 arranged around the rotating shaft 43 in an array, wherein the driving rollers 44 are meshed with the linkage belt 42;

and a telescopic member 45 connected between each driving roller 44 and the rotation shaft 43.

In summary, with reference to fig. 1, it can be seen that:

in fig. 1, the driving gear 5 and the driven gear 6 are kept in a meshed state, at the moment, the eccentric roller 3 and the driving gear 5 are driven by the motor to rotate, the eccentric roller 3 drives the cutter assembly 2 to lift while rotating, the driving gear 5 drives the driven gear 6 to rotate while rotating, the driven gear 6 drives the rotating shaft 43 to rotate, the rotating shaft 43 rotates to drive the corresponding rotating part 41 to rotate, the rotating part 41 rotates to realize the transmission of the whole transmission assembly 4, and then the driving roller and the whole automatic feeding mechanism 1 are driven to transmit. Therefore, double driving of cutting and automatic feeding can be realized based on one motor. Further, for the transmission of the transmission assembly 4, when the length of the telescopic member 45 in any one of the rotating members 41 is changed, the rotation ratio between the two rotating members 41 is changed, and the rotation ratio between the corresponding eccentric roller 3 and the driving roller is also changed. Taking fig. 4 as an example, assuming that the length of the telescopic member 45 of the rotating member 41 (coaxial with the driven gear 6) at a is elongated, thereby causing the rotating member 41 at a to rotate 360 °, and the rotating member 41 (coaxial with the driving roller) at b to rotate more than 360 °, if the two rotating members 41 maintain the same rotating diameter, the conveying distance of the automatic feeding mechanism 1 corresponding to one moving stroke is L, so that in the case that the rotating diameter of the rotating member 41 at a is larger than that of the rotating member 41 at b, the conveying distance of the automatic feeding mechanism 1 corresponding to one moving stroke should be larger than L, thereby effectively changing the corresponding cutting length (in one cutting process, the feeding speed becomes faster, and the feeding length increases).

Specifically, with respect to the above disclosed structure, a preferred embodiment of the cutter assembly 2 is provided in the present invention; the cutter assembly 2 includes:

a lifting plate 21;

a cutting knife 22 and an elastic material pressing piece 23 which are arranged at the bottom of the lifting plate 21, and when the elastic material pressing piece 23 is not compressed, the length of the elastic material pressing piece 23 is not less than that of the cutting knife 22.

Above-mentioned, elasticity pressure material 23 includes elasticity telescopic link 25 and connects in the pressure flitch 26 of elasticity telescopic link 25 bottom, and elasticity telescopic link 25 includes:

an outer rod 27;

an inner rod 28, and one end of the inner rod 28 extends into the outer rod 27;

a swage spring 29 connected between the inner rod 28 and the outer rod 27, and the swage spring 29 is always defined inside the outer rod 27.

In addition, a portal frame 7 is fixed at the top of the automatic feeding mechanism 1, the cutter assembly 2 is installed inside the portal frame 7, and a limiting spring 24 is connected between the top of the lifting plate 21 and the top of the portal frame 7; the automatic feeding mechanism 1 is provided with a cutting cavity between adjacent conveying rollers, and the cutting cavity is positioned right below the cutting knife 22.

In summary, with reference to fig. 1, 8-10, it can be known that:

in fig. 1, the driving gear 5 and the driven gear 6 are maintained in a meshed state, and at this time, the eccentric roller 3 and the driving gear 5 are driven to rotate by the motor, taking clockwise rotation as an example, the eccentric roller 3 drives the lifting plate 21, the cutting knife 22 and the elastic pressing piece 23 to descend while rotating, so as to approach the automatic feeding mechanism 1 to prepare for cutting, and the limit spring 24 is compressed; meanwhile, the quantitative feeding of the automatic feeding mechanism 1 is realized through the linkage of the integral linkage mechanism;

in fig. 8, the driving gear 5 rotates to a position just disengaged from the driven gear 6, and the pressing plate 26 at the bottom of the elastic pressing member 23 is just pressed against the workpiece to be cut; at the position, the eccentric roller 3 and the driving gear 5 continue to rotate clockwise, and at the moment, the driving gear 5 is disengaged from the driven gear 6, so that the whole linkage mechanism does not move, the corresponding automatic feeding mechanism 1 stops conveying, and the workpiece is stably positioned at the current position;

in fig. 9, the driving gear 5 rotates to the middle position of the opening corresponding to the driven gear 6, and the cutter assembly 2 descends to the lowest position, the material pressing spring 29 is compressed, and the cutting blade 22 finishes cutting the workpiece; in the position, the eccentric roller 3 and the driving gear 5 continue to rotate clockwise;

in fig. 10, the driving gear 5 rotates to a position to be engaged with the driven gear 6, and particularly in the rotating process from fig. 9 to fig. 10, the lifting plate 21 can be pulled to rise based on the resilience of the limiting spring 24, so that the cutting knife 22 is lifted back and returns to the position shown in fig. 8, and the integral cutting knife assembly 2 is ensured not to interfere with the workpiece; at the position, the eccentric roller 3 and the driving gear 5 continue to rotate clockwise, at the moment, the driving gear 5 and the driven gear 6 are meshed again, and therefore the whole linkage mechanism is driven to move, the automatic feeding mechanism 1 is driven to convey, and automatic feeding of workpieces is completed.

In summary, to ensure the continuous processing of the integral vertical cutting and processing device, the adjustment of the rotating diameter of the rotating member 41 can be set in the cutting process shown in fig. 8-10, at this time, the integral linkage mechanism does not move, the adjustment operation is convenient, and the telescopic member 45 can be preferably an electric telescopic rod, so that the full-automatic adjustment and control of the integral vertical cutting and processing device can be effectively realized.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides a vertical cutting processingequipment of automotive interior part processing which characterized in that includes:

the automatic feeding mechanism (1) comprises a plurality of conveying rollers capable of synchronously rotating in the same direction, and the plurality of conveying rollers comprise a driving roller;

the cutter component (2) can lift, and the cutter component (2) is arranged above the automatic feeding mechanism (1);

the automatic feeding mechanism comprises a variable-speed linkage mechanism, the cutter component (2) drives the automatic feeding mechanism (1) to convey through the linkage mechanism in a timing mode in the lifting process, one-time descending and one-time rising of the cutter component (2) are combined into one moving stroke, and the linkage mechanism is further used for changing the conveying distance of the automatic feeding mechanism (1) in one moving stroke.

2. The vertical cutting processing device for processing an automotive interior part according to claim 1, characterized in that the linkage mechanism comprises:

the rotatable eccentric roller (3) drives the cutter assembly (2) to lift through the rotation of the eccentric roller (3);

the transmission component (4) is variable in speed, and the transmission component (4) is used for realizing linkage between rotation of the eccentric roller (3) and transmission of the automatic feeding mechanism (1);

the connecting component is matched between the eccentric roller (3) and the transmission component (4) and is used for realizing the timing connection of the eccentric roller (3) and the transmission component (4).

3. The vertical cutting processing apparatus for processing an automotive interior part according to claim 2, characterized in that: the connecting assembly includes:

the driving gear (5) is an incomplete gear with an opening formed in one side, and the driving gear (5) and the eccentric roller (3) are coaxially mounted;

the driven gear (6) can be meshed with the driving gear (5), the driven gear (6) is a complete gear, and the driven gear (6) is used for driving the transmission assembly (4) to transmit; when the driving gear (5) rotates to the middle position of the opening and corresponds to the driven gear (6), the cutter assembly (2) descends to the lowest position.

4. The vertical cutting machining device for machining automotive interior parts according to claim 3, characterized in that the transmission assembly (4) comprises:

two rotating members (41), wherein one rotating member (41) is coaxially mounted with the driving roller, and the other rotating member (41) is coaxially mounted with the driven gear (6);

the linkage belt (42) is sleeved on the two rotating pieces (41) and is transmitted along with the rotation of the rotating pieces (41).

5. The vertical cutting processing device for processing automotive interior parts according to claim 4, characterized in that the rotary member (41) comprises:

a rotating shaft (43);

n driving rollers (44) are arranged around the rotating shaft (43) in an array mode, and the driving rollers (44) are meshed with the linkage belt (42);

a telescopic member (45) connected between each of the driving rollers (44) and the rotary shaft (43).

6. The vertical cutting processing device for processing automotive interior parts according to any one of claims 1 to 5, characterized in that the cutter assembly (2) comprises:

a lifting plate (21);

the cutting knife (22) and the elastic pressing piece (23) are installed at the bottom of the lifting plate (21), and when the elastic pressing piece (23) is not compressed, the length of the elastic pressing piece (23) is not smaller than that of the cutting knife (22).

7. The vertical cutting processing apparatus for processing an automotive interior part according to claim 6, characterized in that: the elastic pressing piece (23) comprises an elastic telescopic rod (25) and a pressing plate (26) connected to the bottom of the elastic telescopic rod (25).

8. The vertical cutting processing device for the processing of automotive interior parts according to claim 7, characterized in that the elastic telescopic rod (25) comprises:

an outer rod (27);

an inner rod (28), wherein one end of the inner rod (28) extends into the outer rod (27);

the swaging spring (29) is connected between the inner rod (28) and the outer rod (27), and the swaging spring (29) is always limited inside the outer rod (27).

9. The vertical cutting processing apparatus for processing an automotive interior part according to claim 6, characterized in that: the automatic feeding mechanism is characterized in that a portal frame (7) is fixed to the top of the automatic feeding mechanism (1), the cutter assembly (2) is installed inside the portal frame (7), and a limiting spring (24) is connected between the top of the lifting plate (21) and the top of the portal frame (7).

10. The vertical cutting processing apparatus for processing an automotive interior part according to claim 6, characterized in that: and a cutting cavity positioned between adjacent conveying rollers is arranged on the automatic feeding mechanism (1), and the cutting cavity is positioned under the cutting knife (22).

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