CN117001320A - Automatic installation system of boneless wiper of new energy automobile - Google Patents

Abstract

The invention discloses an automatic installation system of a boneless wiper of a new energy automobile, wherein a lower assembly plate mechanism comprises a transmission belt and a plurality of lower assembly plates which are rotatably connected to a rack, the upper assembly plate mechanism comprises a cross beam, and a first upper assembly plate, a second upper assembly plate and a third upper assembly plate which are connected below the cross beam in a lifting manner.

Description

Automatic installation system of boneless wiper of new energy automobile

Technical Field

The invention relates to an automatic installation system of a boneless wiper of a new energy automobile.

Background

The patent with the publication number of CN114571230A discloses an automatic assembling system and an assembling method for an automobile boneless wiper, wherein the assembling system comprises a conveying mechanism, a spring assembly mechanism, a left end glue button assembly mechanism, a right end glue button assembly mechanism, an automatic brush head assembly material distributing system, a robot system, a material collecting mechanism, a main control and a robot control cabinet.

The main structure of the automatic installation system of the boneless wiper of the new energy automobile in the prior art is basically the same as the technical scheme disclosed in the patent, and the automatic installation system has the following defects: the connection of each assembly step of the boneless wiper mainly depends on the transfer and clamping of various complex mechanical arms, the arrangement of a large number of mechanical arms obviously greatly improves the manufacturing cost of equipment, and the arrangement of fewer mechanical arms can lead to the delay of assembly beats, so that the assembly efficiency of the boneless wiper is greatly limited.

Disclosure of Invention

The invention aims to overcome the defects of the prior art, and provides an automatic installation system for the boneless wiper of the new energy automobile, which has the advantages of simplified structure, low manufacturing cost and high efficiency.

The technical scheme of the invention is as follows: the automatic mounting system for the boneless wiper of the new energy automobile comprises an upper assembly plate mechanism, a lower assembly plate mechanism, a buckle assembly mechanism, a spring assembly mechanism, a rubber strip assembly mechanism, a shield assembly mechanism and an end cap assembly mechanism;

the lower assembly plate mechanism comprises a transmission belt rotatably connected to the frame and a plurality of lower assembly plates fixed on the transmission belt at equal intervals, and the upper assembly plate mechanism comprises a beam, a first upper assembly plate, a second upper assembly plate and a third upper assembly plate which are connected below the beam in a lifting manner;

the elastic sheet assembling mechanism, the protective cover assembling mechanism and the end cap assembling mechanism all comprise a left machine body and a right machine body which are arranged on two sides of the machine frame, five stations respectively corresponding to the buckle assembly assembling mechanism, the elastic sheet assembling mechanism, the adhesive tape assembling mechanism, the protective cover assembling mechanism and the end cap assembling mechanism are arranged on the machine frame, and the assembly of corresponding parts is stopped when each lower assembling plate moves to the corresponding station;

the middle part of the top end of the lower assembly plate is provided with a limit groove corresponding to the buckle component, the top ends of the lower assembly plates at two sides of the limit groove are respectively provided with two long grooves, the two long grooves are respectively connected with a telescopic plate through springs, the top surfaces of the two telescopic plates are flush with the top surface of the lower assembly plate when the telescopic plates are not pressed, the top parts of the two telescopic plates are respectively provided with a slot, the two slots are communicated with the upper end of the limit groove, and the outer ends of the two telescopic plates are sloping surfaces which incline downwards;

the output end of the buckle component assembling mechanism is positioned above one lower assembling plate and corresponds to the limiting groove, the buckle component assembling mechanism outputs a buckle component and enables the buckle component to fall into the limiting groove, and two fixed side plates of the buckle component are arranged upwards;

the bottom of the first upper assembly plate is provided with a first guide groove of two corresponding elastic pieces, the middle of the first upper assembly plate is also provided with a groove, after the first upper assembly plate is abutted against the lower assembly plate, the groove is arranged corresponding to the limit groove, a pressing plate is connected in the groove in a lifting manner, two output ends of the elastic piece assembly mechanism are respectively aligned with each other and input an elastic piece into the corresponding first guide groove, the two elastic pieces respectively penetrate into the first guide groove, two ends of the elastic pieces are respectively positioned at the outer sides of two ends of the first guide groove, after the elastic pieces penetrate into the first guide groove, the pressing plate downwards presses the side plates of the buckle assembly, so that the two side plates respectively bend and clamp the outer sides of the two elastic pieces;

the bottom of the second upper assembly plate is provided with a second guide groove corresponding to the adhesive tape, after the second upper assembly plate is abutted with the lower assembly plate, the output end of the adhesive tape assembly mechanism is aligned with and outputs an adhesive tape between the second guide groove and the slot, and the adhesive tape is input and clamped between the two elastic sheets;

the bottom of the third upper assembly plate is provided with a clearance groove corresponding to the adhesive tape and the elastic sheet, after the third upper assembly plate is abutted with the lower assembly plate, two output ends of the shield assembly mechanism are respectively aligned with the outer ends of the telescopic plates and output a shield in the direction, the shield extrusion telescopic plates are clamped into and sleeved on the two ends of the two elastic sheets, the outer ends of the two shields are respectively positioned outside the long grooves, and the outer ends of the two shields are also respectively positioned at the inner sides of the end parts of the elastic sheets;

after the shield is assembled, the lower assembly plate continues to move forwards by one station, the third upper assembly plate moves synchronously until reaching the corresponding position of the end cap assembly mechanism, two output ends of the end cap assembly mechanism are respectively aligned with the elastic pieces protruding out of the two ends of the lower assembly plate and the third upper assembly plate and output an end cap to the elastic pieces, and the two end caps are respectively matched with the two ends of the elastic pieces and buckled with the corresponding shield ends.

Further, one end of the frame is also fixed with a servo motor, and the servo motor drives the transmission belt.

Further, a plurality of hydraulic cylinders for driving the upper assembly plates to lift are arranged on the cross beam, and a guide rail and a driving trolley corresponding to the third upper assembly plate are further arranged on the cross beam.

Further, the outer ends of the two elongated slots respectively extend to two ends of the lower assembly plate, and the bottom walls of the two elongated slots are also provided with mounting holes corresponding to the springs.

Further, an auxiliary supporting block is also connected below the output ends of the elastic sheet assembling mechanism and the adhesive tape assembling mechanism in a telescopic manner respectively, and when the elastic sheet and the adhesive tape are assembled, each auxiliary supporting block extends out and is inserted between the telescopic plate and the bottom wall of the long groove respectively.

Further, the upper end of the frame is also provided with a plurality of auxiliary supporting plates, each auxiliary supporting plate is arranged corresponding to each station, and when each lower assembly plate moves to the corresponding station for assembly, the bottom of each lower assembly plate is abutted against the top of the auxiliary supporting plate.

Further, balls or copper bars are further arranged at the bottom of each lower assembly plate.

Further, the four corners of the top of each lower assembly plate are respectively provided with bowl-shaped guide holes, and the bottoms of the first upper assembly plate, the second upper assembly plate and the third upper assembly plate are provided with corresponding guide convex columns.

Further, a hydraulic cylinder for driving the pressing plate to lift is fixed at the top of the first upper assembly plate.

Further, the slot, the first guide groove and the second guide groove are provided with triangular inlets at the ends.

The beneficial effects of the invention are as follows: according to the invention, continuous assembly operation is carried out, namely when a first lower assembly plate completes assembly of a station, the next lower assembly plate simultaneously carries out assembly of the last station, and as each lower assembly plate moves along with a driving belt, the motion track of the driving belt is an arc track with semicircular middle square two ends, each lower assembly plate carries out circulating motion along the track, so that efficient circulating processing is realized; and because the processing of each station is carried out through the cooperation of lower assembly plate and each upper assembly plate, the different insertion channels of each part are constituteed to lower assembly plate and each upper assembly plate after the cooperation, and the displacement and the assembly of work piece need not the arm and cooperate during its assembly, compare complicated assembly equipment in the prior art, and above-mentioned structure still has simple structure, low in manufacturing cost's advantage.

Drawings

FIG. 1 is a top view of the present invention with the upper mounting plate mechanism removed;

FIG. 2 is a top view of the lower mounting plate of the present invention;

FIG. 3 is a cross-sectional view of the lower mounting plate of the present invention after the snap assembly is provided;

FIG. 4 is a schematic view of the assembled spring plate according to the present invention;

FIG. 5 is a cross-sectional view of the assembled spring of the present invention;

FIG. 6 is a schematic view of the construction of the present invention when the adhesive strip is assembled;

FIG. 7 is a cross-sectional view of the present invention when the adhesive strip is assembled;

FIG. 8 is a schematic view of the assembled shield of the present invention;

FIG. 9 is a cross-sectional view of the present invention when the shield is assembled;

FIG. 10 is a schematic view of the present invention assembled with an end cap;

fig. 11 is a cross-sectional view of the invention as it is assembled with the end cap.

In the figure: the lower assembly plate mechanism 1, the buckle assembly mechanism 2, the elastic sheet assembly mechanism 3, the adhesive tape assembly mechanism 4, the shield assembly mechanism 5, the end cap assembly mechanism 6, the transmission belt 7, the lower assembly plate 8, the first upper assembly plate 9, the second upper assembly plate 10, the third upper assembly plate 11, the buckle assembly 13, the limit groove 14, the long groove 15, the spring 16, the expansion plate 17, the slot 18, the groove 19, the pressing plate 20, the elastic sheet 21, the adhesive tape 22, the shield 23, the end cap 24, the servo motor 25, the auxiliary supporting block 26 and the guide hole 27.

Detailed Description

The technical scheme of the invention is further specifically described below through examples and with reference to the accompanying drawings.

As shown in fig. 1, the automatic installation system of the boneless wiper of the new energy automobile comprises an upper assembly plate mechanism, a lower assembly plate mechanism 1, a buckle assembly mechanism 2, a spring assembly mechanism 3, a rubber strip assembly mechanism 4, a shield assembly mechanism 5 and an end cap assembly mechanism 6;

the lower assembly plate mechanism 1 comprises a transmission belt 7 rotatably connected to a frame and a plurality of lower assembly plates 8 fixed on the transmission belt 7 at equal distances, and the upper assembly plate mechanism comprises a cross beam (not shown), and a first upper assembly plate 9, a second upper assembly plate 10 and a third upper assembly plate 11 which are connected below the cross beam in a lifting manner;

as shown in fig. 2 and 3, the middle part of the top end of the lower assembly plate 8 is provided with a limit groove 14 corresponding to the buckle assembly 13, the top ends of the lower assembly plate 8 at two sides of the limit groove 14 are respectively provided with two elongated grooves 15, the two elongated grooves 15 are respectively connected with a telescopic plate 17 through springs 16, the top surfaces of the two telescopic plates 17 are flush with the top surface of the lower assembly plate 8 when the telescopic plates 17 are not pressed, the top parts of the two telescopic plates 17 are respectively provided with a slot 18, the two slots 18 are communicated with the upper ends of the limit groove 14, and the outer ends of the two telescopic plates 17 are inclined surfaces which incline downwards;

the output end of the buckle component assembling mechanism 2 is positioned above one lower assembling plate 8 and is arranged corresponding to the limit groove 14, the buckle component assembling mechanism 2 outputs one buckle component 13 and enables the buckle component 13 to fall into the limit groove 14, and two fixed side plates of the buckle component 13 are upwards arranged;

as shown in fig. 4 and 5, the lower assembly plate 8 that receives the bayonet component moves forward by one station, to the corresponding position of the spring assembly mechanism 3, the first upper assembly plate 9 descends and is abutted against the lower assembly plate 8, the bottom of the first upper assembly plate 9 has the first guide grooves of two corresponding spring plates 21, the middle part of the first upper assembly plate 9 also has a groove 19, the groove 19 is arranged corresponding to the limit groove 14, a pressing plate 20 is also connected in the groove 19 in a lifting manner, the spring assembly mechanism 3 comprises a left machine body and a right machine body, the left machine body and the right machine body are respectively positioned at two sides of the frame, the output ends of the left machine body and the right machine body are respectively aligned and input a spring plate 21 into the corresponding first guide grooves, the two spring plates 21 respectively penetrate into the first guide grooves, and two ends of the spring plates are respectively positioned at the outer sides of the two ends of the first guide grooves, and after the spring plates 21 penetrate into the first guide grooves, the pressing plate 20 downwards presses the side plates of the buckle component 13, so that the two side plates respectively bend and clamp the outer sides of the two spring plates 21;

as shown in fig. 6 and 7, after the elastic sheet 21 is assembled, the first upper assembly plate 9 is reset, the lower assembly plate 8 continues to move forward by one station until the adhesive tape assembly mechanism 4 is at the corresponding position, the second upper assembly plate 10 descends and is abutted against the lower assembly plate 8, the bottom of the second upper assembly plate 10 is provided with a second guide groove corresponding to the adhesive tape 22, the output end of the adhesive tape assembly mechanism 4 aligns and outputs an adhesive tape 22 between the second guide groove and the slot 18, and the adhesive tape 22 is input and clamped between the two elastic sheets 21;

as shown in fig. 8 and 9, after the adhesive tape 22 is assembled, the second upper assembly plate 10 is reset, the lower assembly plate 8 continues to move forward by one station until reaching the corresponding position of the shield assembly mechanism 5, the third upper assembly plate 11 is lowered and is abutted against the lower assembly plate 8, the bottom of the third upper assembly plate 11 is provided with a clearance groove corresponding to the adhesive tape 22 and the elastic piece 21, the shield assembly mechanism 5 comprises a left machine body and a right machine body, the left machine body and the right machine body are respectively positioned at two sides of the frame, the output ends of the left machine body and the right machine body are respectively aligned with the outer ends of the expansion plate 17 and output a shield 23 in the direction, under the action of the slope of the end part of the expansion plate 17, the expansion plate 17 is extruded by the expansion plate 17 when the shield 23 is output, the expansion plate 17 is enabled to descend, the shield 23 is clamped into the expansion plate 17 and the third upper assembly plate 11 to be sleeved at two ends of the two elastic pieces 21, the end parts of the shield 23 are matched with two ends of the buckle assembly 13, the outer ends of the two shields 23 are respectively positioned outside the long grooves 15, and the outer ends of the two shields 23 are respectively positioned at the inner sides of the end parts of the elastic pieces 21;

as shown in fig. 10 and 11, after the shield 23 is assembled, the lower assembly plate 8 continues to move forward by one station, the third upper assembly plate 11 moves synchronously until reaching the corresponding position of the end cap assembly mechanism 6, the end cap assembly mechanism 6 comprises a left machine body and a right machine body, the left machine body and the right machine body are respectively positioned at two sides of the frame, the output ends of the left machine body and the right machine body are respectively aligned with the elastic pieces 21 protruding from the two ends of the lower assembly plate 8 and the third upper assembly plate 11 and output an end cap 24 to the elastic pieces 21, the two end caps 24 are respectively matched at the two ends of the elastic pieces 21 and are buckled with the corresponding ends of the shield 23,

at this time, the boneless wiper is assembled, the third upper assembly plate 12 is reset, the lower assembly plate 8 continues to move forward until the lower assembly plate is inclined downwards along the movement track of the conveyor belt and overturned to the bottom of the rack, and the boneless wiper is poured out to the output port;

the third upper mounting plate 11 is reciprocally displaced between the hood assembly mechanism 5 and the end cap assembly mechanism 6, and when the end cap 6 is assembled, the hood assembly mechanism 5 pauses and waits for the third upper mounting plate 11 to return.

The structure performs continuous assembly operation, namely when the first lower assembly plate 8 completes the assembly of a station, the next lower assembly plate 8 simultaneously performs the assembly of the last station, and as each lower assembly plate 8 moves along with the driving belt 7, the movement track of the driving belt 7 is an arc track with semicircular middle square two ends, each lower assembly plate 8 performs circular movement along the track, and efficient circular processing is further realized; because the processing of each station of the structure is matched with each upper assembly plate through the lower assembly plate 8, an insertion channel of each component is formed, and when the structure is assembled, the displacement and the assembly of the workpiece do not need mechanical arms to be matched, compared with complex assembly equipment in the prior art, the structure also has the advantages of simple structure and low manufacturing cost.

In another embodiment, as shown in fig. 1, a servo motor 25 is further fixed at one end of the frame, and the servo motor 25 drives the driving belt 7, so that the driving belt 7 can more precisely drive each lower assembly plate 8 to displace.

In another embodiment, the beam is provided with a plurality of hydraulic cylinders for driving the upper assembly plates to lift, and the beam is also provided with a guide rail and a driving trolley corresponding to the third upper assembly plate 11.

In another embodiment, as shown in fig. 2, the outer ends of the two elongated slots 15 respectively extend to two ends of the lower assembly plate 8, and the bottom walls of the two elongated slots 15 are further provided with mounting holes corresponding to the springs 16.

In another embodiment, the length and width of the expansion plate 17 correspond to the length and width of the long groove 15.

In another embodiment, the two side plates of the buckle assembly 13 are inclined inward, so that the pressing plate 20 bends and clamps the outer sides of the two spring plates 21 when the pressing plate is downward.

In another embodiment, an auxiliary supporting block 26 is further connected under the output ends of the elastic sheet assembling mechanism 3 and the adhesive tape assembling mechanism 4 in a telescopic manner, and when the elastic sheet 21 and the adhesive tape 22 are assembled, each auxiliary supporting block 26 extends out and is inserted between the telescopic plate 17 and the bottom wall of the long slot 15, so as to avoid assembly errors caused by descending of the telescopic plate 17.

In another embodiment, the upper end of the frame is further provided with a plurality of auxiliary supporting plates, each auxiliary supporting plate is arranged corresponding to each station, and when each lower assembly plate 8 moves to the corresponding station for assembly, the bottom of each lower assembly plate 8 is abutted against the top of the auxiliary supporting plate, so as to avoid deformation of the lower assembly plate 8 under the action of the upper assembly plate.

In another embodiment, the bottom of each of the lower mounting plates 8 is further provided with balls or copper bars to reduce friction when contacting the accessory support plate.

In another embodiment, as shown in fig. 2, the top four corners of each of the lower mounting plates 8 are further provided with bowl-shaped guide holes 27, and the bottoms of the first upper mounting plate 9, the second upper mounting plate 10 and the third upper mounting plate 11 are provided with corresponding guide posts to ensure that the lower mounting plate 8 and the upper mounting plate are accurately abutted.

In another embodiment, as shown in fig. 4, a hydraulic cylinder for driving the pressing plate 20 to lift is further fixed on the top of the first assembly plate.

In another embodiment, the slot 18, the first guide slot and the second guide slot each have triangular inlets at their ends to facilitate the input of a corresponding workpiece.

Claims (10)

1. The automatic mounting system for the boneless wiper of the new energy automobile is characterized by comprising an upper assembly plate mechanism, a lower assembly plate mechanism (1), a buckle assembly mechanism (2), a spring assembly mechanism (3), a rubber strip assembly mechanism (4), a shield assembly mechanism (5) and an end cap assembly mechanism (6);

the lower assembly plate mechanism (1) comprises a transmission belt (7) rotatably connected to the frame and a plurality of lower assembly plates (8) fixed on the transmission belt (7) at equal intervals, and the upper assembly plate mechanism comprises a beam, a first upper assembly plate (9), a second upper assembly plate (10) and a third upper assembly plate (11) which are connected below the beam in a lifting manner;

the elastic sheet assembling mechanism (3), the protective cover assembling mechanism (5) and the end cap assembling mechanism (6) comprise a left machine body and a right machine body which are arranged on two sides of the machine frame, five stations respectively corresponding to the buckle assembly assembling mechanism (2), the elastic sheet assembling mechanism (3), the adhesive tape assembling mechanism (4), the protective cover assembling mechanism (5) and the end cap assembling mechanism (6) are arranged on the machine frame, and each lower assembling plate (8) pauses the assembly of corresponding parts when moving to the corresponding station;

the middle part of the top end of the lower assembly plate (8) is provided with a limit groove (14) corresponding to the buckle assembly (13), the top ends of the lower assembly plates (8) on two sides of the limit groove (14) are respectively provided with two long grooves (15), the two long grooves (15) are respectively connected with a telescopic plate (17) through springs (16), the top surfaces of the two telescopic plates (17) are flush with the top surface of the lower assembly plate (8) when the telescopic plates (17) are not pressed, the tops of the two telescopic plates (17) are respectively provided with a slot (18), the two slots (18) are communicated with the upper ends of the limit groove (14), and the outer ends of the two telescopic plates (17) are inclined downward slopes;

the output end of the buckle assembly mechanism (2) is positioned above one lower assembly plate (8) and corresponds to the limit groove (14), the buckle assembly mechanism (2) outputs one buckle assembly (13) and enables the buckle assembly (13) to fall into the limit groove (14), and two fixed side plates of the buckle assembly (13) are arranged upwards;

the bottom of the first upper assembly plate (9) is provided with first guide grooves of two corresponding elastic pieces (21), the middle part of the first upper assembly plate (9) is also provided with a groove (19), after the first upper assembly plate (9) is abutted against the lower assembly plate (8), the groove (19) is arranged corresponding to the limit groove (14), a pressing plate (20) is further connected in the groove (19) in a lifting manner, two output ends of the elastic piece assembly mechanism (3) are respectively aligned with each other and input with an elastic piece (21) into the corresponding first guide groove, the two elastic pieces (21) respectively penetrate into the first guide grooves, the two ends of the elastic pieces are respectively positioned at the outer sides of the two ends of the first guide grooves, and after the elastic pieces (21) penetrate into each other, the pressing plate (20) downwards bends the side plates of the buckling component (13) to enable the two side plates to respectively clamp the outer sides of the two elastic pieces (21);

the bottom of the second upper assembly plate (10) is provided with a second guide groove corresponding to the adhesive tape (22), after the second upper assembly plate (10) is abutted with the lower assembly plate (8), the output end of the adhesive tape assembly mechanism (4) is aligned with the output end of the adhesive tape assembly mechanism and outputs an adhesive tape (22) between the second guide groove and the slot (18), and the adhesive tape (22) is input and clamped between the two elastic sheets (21);

the bottom of the third upper assembly plate (11) is provided with a clearance groove corresponding to the adhesive tape (22) and the elastic sheet (21), after the third upper assembly plate (11) is abutted with the lower assembly plate (8), two output ends of the shield assembly mechanism (5) are respectively aligned with the outer ends of the expansion plates (17) and output shields (23) in the direction, the shields (23) extrude the expansion plates (17) to be clamped into and sleeved on the two ends of the two elastic sheets (21), the outer ends of the two shields (23) are respectively positioned outside the long grooves (15), and the outer ends of the two shields (23) are respectively positioned on the inner sides of the end parts of the elastic sheet (21);

after the shield (23) is assembled, the lower assembly plate (8) continues to move forwards by one station, the third upper assembly plate (11) moves synchronously until the end cap assembly mechanism (6) is at the corresponding position, two output ends of the end cap assembly mechanism (6) are respectively aligned with the spring pieces (21) protruding out of the two ends of the lower assembly plate (8) and the third upper assembly plate (11) and output an end cap (24) to the spring pieces, and the two end caps (24) are respectively matched with the two ends of the spring pieces (21) and are buckled with the corresponding end parts of the shield (23).

2. The automatic installation system of the boneless wiper of the new energy automobile according to claim 1, wherein one end of the frame is also fixed with a servo motor (25), and the servo motor (25) drives the driving belt (7).

3. The automatic installation system of the boneless wiper of the new energy automobile according to claim 2, wherein a plurality of hydraulic cylinders for driving each upper assembly plate to lift are arranged on the cross beam, and a guide rail and a driving trolley corresponding to the third upper assembly plate (11) are also arranged on the cross beam.

4. A new energy automobile boneless wiper automatic mounting system according to claim 3, characterized in that the outer ends of the two long grooves (15) extend to the two ends of the lower assembly plate (8), and the bottom walls of the two long grooves (15) are provided with mounting holes corresponding to the springs (16).

5. The automatic installation system for the boneless wiper of the new energy automobile according to claim 4, wherein an auxiliary supporting block (26) is also connected below the output ends of the elastic sheet assembling mechanism (3) and the adhesive tape assembling mechanism (4) in a telescopic manner respectively, and when the elastic sheet (21) and the adhesive tape (22) are assembled, each auxiliary supporting block (26) extends out and is inserted between the bottom walls of the telescopic plate (17) and the long groove (15) respectively.

6. The automatic installation system for the boneless wiper of the new energy automobile according to claim 5, wherein a plurality of auxiliary supporting plates are further arranged at the upper end of the rack, each auxiliary supporting plate is arranged corresponding to each station, and when each lower assembly plate (8) moves to the corresponding station for assembly, the bottom of each lower assembly plate (8) is abutted against the top of the auxiliary supporting plate.

7. The automatic installation system for the boneless wiper of a new energy automobile according to claim 6, wherein the bottom of each lower assembly plate (8) is also provided with balls or copper bars.

8. The automatic installation system for the boneless wiper of the new energy automobile according to claim 7, wherein the top four corners of each lower assembly plate (8) are respectively provided with bowl-shaped guide holes (27), and the bottoms of the first upper assembly plate (9), the second upper assembly plate (10) and the third upper assembly plate (11) are provided with corresponding guide convex columns.

9. The automatic installation system for the boneless wiper of the new energy automobile according to claim 8, wherein a hydraulic cylinder for driving the pressing plate (20) to lift is further fixed at the top of the first upper assembly plate (9).

10. The automatic boneless wiper mounting system for new energy vehicles according to claim 9, wherein the slot (18), the first guide groove and the second guide groove have triangular inlets at the ends thereof.