CN115007745B

CN115007745B - Support extrusion processing device for photovoltaic equipment

Info

Publication number: CN115007745B
Application number: CN202210947059.6A
Authority: CN
Inventors: 周欣星
Original assignee: Yancheng Jienuo Machinery Co ltd
Current assignee: Yancheng Jienuo Machinery Co ltd
Priority date: 2022-08-09
Filing date: 2022-08-09
Publication date: 2022-11-04
Anticipated expiration: 2042-08-09
Also published as: CN115007745A

Abstract

The invention provides a support extrusion processing device for photovoltaic equipment, which relates to the field of extrusion processing and comprises a support body, wherein a driving shaft is rotatably arranged on a support plate A, and the left end of the driving shaft is connected with an output shaft of a motor; the right end of the driving shaft is provided with a gear A; the shear frame is provided with a mounting plate; the top of the mounting plate is provided with a guide groove; the left side and the right side of the auxiliary straightening piece are provided with follow-up racks. According to the invention, through the matching of a plurality of components, the guiding work, the extruding work, the basic forming work, the final forming work, the finishing work and the cutting-off work of the steel structure sheet can be synchronously realized under the driving of the same motor, the driving assembly is optimized, the arrangement amount of the driving assembly is extremely simple, and the problems that certain linkage is lacked among the extruding structure, the guide vane structure and the shearing structure in the existing device and the optimized design of the driving assembly used by the three structures is not reasonable enough are solved.

Description

Support extrusion processing device for photovoltaic equipment

Technical Field

The invention relates to the technical field of extrusion processing, in particular to a support extrusion processing device for photovoltaic equipment.

Background

The raw materials of the mounting bracket for the photovoltaic equipment are mostly steel sheets, and the steel sheets cannot be directly used as the mounting bracket for the photovoltaic equipment, so that the steel sheets need to be subjected to extrusion processing and other necessary process processing to become the bracket for the photovoltaic equipment, and an extrusion processing device is needed for the extrusion processing of the steel sheets.

When the existing extrusion processing device is used, certain linkage is lacked among the extrusion structure, the guide vane structure and the shearing structure in the device, the optimal design of the driving assemblies for the three structures is not reasonable enough, the three structures are mostly equipped with independent driving assemblies, so many driving assemblies lead to the linear surging of the weight, the volume and the cost of the processing device, in addition, the structure of the existing extrusion processing device is not compact enough, the whole extrusion processing production line of the device is longer, and the space occupancy of the device is larger.

Disclosure of Invention

In view of this, the invention provides a support extrusion processing device for photovoltaic equipment, which has a linkage structure, and through the arrangement of the linkage structure, when a steel-structured sheet is guided, extrusion processing work on the steel-structured sheet can be realized in a linkage manner, and meanwhile, the device is compact in structure and small in size.

The invention provides a purpose and effect of a support extrusion processing device for photovoltaic equipment, which specifically comprises the following steps: the supporting body is provided with supporting plates A at the left end and the right end of the rear side of the top of the supporting body; a support plate B is arranged at the left end and the right end of the central position of the top of the support body; support plates C are arranged at the left end and the right end of the front side of the top of the support body; a motor is arranged on the left side of the support plate A on the left side; a shearing frame is arranged on the rear side of the supporting body; the top of the supporting body is provided with an L-shaped guide plate; a driving shaft is rotatably arranged on the support plate A, and the left end of the driving shaft is connected with an output shaft of a motor; the right end of the driving shaft is provided with a gear A; the shear frame is provided with a mounting plate; the top of the mounting plate is provided with a guide groove; an auxiliary straightening piece is slidably mounted inside the guide groove; the front side of the auxiliary straightening piece is embedded with one end of a spring A, and the other end of the spring A is embedded and mounted on the front side of the guide groove; and the left side and the right side of the auxiliary straightening piece are provided with follow-up racks.

Furthermore, a synchronizing wheel B is arranged at the right end of the guide shaft above the guide shaft and is connected with the synchronizing wheel A through a synchronizing belt.

Furthermore, a gear C is arranged at the left end of the guide shaft, and the two gears C are meshed and connected; and the top of the support body is rotatably provided with a forming shaft.

Furthermore, a first bevel gear is arranged at the top end of the forming shaft on the left side; and a third section of the forming shaft is provided with a synchronizing wheel C.

Furthermore, a base forming roller is arranged on two third sections of the forming shaft, and the base forming roller is of a conical structure.

Furthermore, a second bevel gear is arranged on the circumferential outer wall of the driving shaft and is in meshed connection with the first bevel gear.

Further, a straightening groove is formed in the auxiliary straightening piece; the top of the auxiliary straightening piece is slidably inserted with a shearing piece, and the bottom of the shearing piece is of an inclined structure.

Furthermore, an extrusion wheel is arranged on the middle section of the follow-up shaft; the bottom of the support plate B is rotatably provided with a matching roller; and a guide shaft is rotatably arranged on the support plate C.

Further, a baffle is arranged at the top of the shearing part; the bottom of the baffle is embedded with one end of a spring B, and the other end of the spring B is embedded and mounted at the top of the auxiliary straightening piece.

Further, a final forming roller is arranged on the circumferential outer wall of the driven shaft; and a synchronous wheel D is arranged at the top end of the driven shaft and is connected with the synchronous wheel C through a synchronous belt.

Further, the gear E is an incomplete gear and is meshed and connected with the follow-up rack; the top of the supporting body is also rotatably provided with a driven shaft, and the driven shaft is positioned at the rear side of the forming shaft.

Furthermore, a stress block is arranged in the middle of the top of the baffle, and the top end of the stress block is of an inclined structure; an adjusting groove is formed in the rear side of the shearing frame; the inside slidable mounting of adjustment tank has the sliding block.

Further, a follow-up shaft is rotatably arranged at the top end of the support plate B; a gear B is arranged at the right end of the follow-up shaft and is meshed and connected with the gear A; and a synchronizing wheel A is arranged on the circumferential outer wall of the follow-up shaft.

Furthermore, three sections of the forming shaft are provided with gears D, and the two gears D are meshed and connected; three sections of the forming shaft are also provided with a gear E, and the gear E is positioned above the gear D.

Furthermore, a trigger block is arranged on the adjusting groove, and the bottom end of the trigger block is of an inclined structure; and the right side of the shearing frame is provided with an adjusting screw rod, and the left end of the adjusting screw rod is rotationally connected with the right side of the sliding block.

Advantageous effects

According to the invention, the driving shaft and the gear A are driven to rotate by the motor, so that the gear A drives the follow-up shaft and the extrusion wheel to rotate under the meshing action with the gear B, and the extrusion wheel is matched with the matching roller through rotation to extrude the steel structure sheet in the first step, so that the steel structure sheet is deformed, the foundation for forming a photovoltaic equipment support is laid, and the follow-up work is facilitated.

When the follow-up shaft rotates, the follow-up shaft drives the upper guide shaft to rotate under the action of the synchronous wheel A, the synchronous wheel B and the corresponding synchronous belt, so that the guide shaft enables the two guide shafts to relatively rotate under the meshing action of the two gears C, the guide shafts guide the steel structure sheet between the guide shafts, and the aim of continuously conveying the steel structure sheet to process the steel structure sheet is fulfilled.

And thirdly, when the driving shaft drives the second bevel gear to rotate, the second bevel gear drives the forming shafts on the right side to relatively rotate under the meshing action of the first bevel gear, so that the two forming shafts drive the basic forming roller to rotate under the meshing action of the gear D, the basic forming roller further forms the steel structure sheet by utilizing the self conical structure, and the forming rate of the steel structure sheet is improved.

And (IV) when the forming shaft rotates, the driven shaft and the final forming roller are driven to rotate under the action of the synchronous wheel C, the synchronous wheel D and the corresponding synchronous belt, so that the final forming roller performs final forming on the steel-structure sheet.

When the forming shaft rotates, the gear E is driven to rotate, the gear E intermittently drives the follow-up rack and the auxiliary straightening piece to reciprocate back and forth along the guide groove by utilizing the characteristic that the gear E is an incomplete gear and matching with the spring A, the auxiliary straightening piece shapes and trims the shaped steel sheet entering the straightening groove by utilizing the straightening groove, the final forming effect of the steel sheet is better ensured, and the forming quality of the device is improved.

And the device only needs to rotate the adjusting screw rod to drive the sliding block and the trigger block to move along the adjusting groove, so that the trigger block and the stressed block are staggered and cannot be contacted with the trigger block, and the device can selectively use the cutting function according to the requirements of users.

The invention enables the guiding work, the extruding work, the basic forming work, the final forming work, the finishing work and the cutting work of the steel structure sheet to be synchronously realized under the drive of the same motor through the mutual matching of a plurality of components, optimizes the driving components, ensures that the arrangement quantity of the driving components is extremely simple, is beneficial to the weight and the volume reduction of the device and also beneficial to the saving of the production cost of the device, has compact structure, optimizes the floor area of the device, and saves the floor area of a factory compared with the traditional production line type extrusion processing device.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings of the embodiments will be briefly described below.

The drawings in the following description relate to only some embodiments of the invention and are not intended to limit the invention.

In the drawings:

fig. 1 is a schematic view of the overall structure of a support extrusion processing apparatus for a photovoltaic device according to an embodiment of the present invention.

Fig. 2 is an overall left side structural schematic view of a support extrusion processing apparatus for a photovoltaic device according to an embodiment of the present invention.

Fig. 3 is a schematic view of the entire rear side structure of the support extrusion processing apparatus for a photovoltaic device according to the embodiment of the present invention.

Fig. 4 is a schematic structural view of a forming shaft and a shearing frame of the support extrusion processing device for the photovoltaic equipment according to the embodiment of the invention.

Fig. 5 is a schematic structural view of a guide shaft and an extrusion wheel of the support extrusion processing device for the photovoltaic equipment according to the embodiment of the invention.

Fig. 6 is a schematic structural view of an extrusion wheel and a matching roller of the support extrusion processing device for the photovoltaic equipment according to the embodiment of the invention.

Fig. 7 is a schematic structural view of a driving shaft and a final forming shaft of the support extrusion processing device for the photovoltaic apparatus according to the embodiment of the present invention.

Fig. 8 is a schematic structural view of an auxiliary straightening member and a basic forming roller of the support extrusion processing device for the photovoltaic equipment according to the embodiment of the invention.

Fig. 9 is a schematic view of a half-section structure of a cutting frame of the support extrusion processing apparatus for a photovoltaic device according to the embodiment of the present invention.

Fig. 10 is a schematic half-sectional view of an auxiliary straightening part of the support extrusion processing device for the photovoltaic equipment, according to the embodiment of the invention.

List of reference numerals

1. A support body; 101. a support plate A; 102. a support plate B; 103. a support plate C; 104. a motor; 105. a drive shaft; 106. a gear A; 107. a follower shaft; 108. a gear B; 109. a synchronous wheel A; 1010. an extrusion wheel; 1011. a mating roller; 1012. a guide shaft; 1013. a synchronous wheel B; 1014. a gear C; 1015. forming a shaft; 1016. a first bevel gear; 1017. a synchronizing wheel C; 1018. a base forming roll; 1019. a gear D; 1020. a gear E; 1021. a driven shaft; 1022. a final forming roller; 1023. a synchronizing wheel D; 1024. a second bevel gear; 2. a shear frame; 201. mounting a plate; 202. a guide groove; 203. an auxiliary straightening piece; 204. a spring A; 205. a follower rack; 206. straightening the groove; 207. a cutting member; 208. a baffle plate; 209. a spring B; 2010. a stress block; 2011. an adjustment groove; 2012. a slider; 2013. a trigger block; 2014. adjusting a screw rod; 3. a guide plate.

Detailed Description

In order to make the objects, aspects and advantages of the embodiments of the present invention more apparent, the embodiments of the present invention will be described in detail with reference to the accompanying drawings. Unless otherwise indicated, terms used herein have the ordinary meaning in the art. Like reference numerals in the drawings denote like elements.

Example (b): please refer to fig. 1 to 10:

the invention provides a support extrusion processing device for photovoltaic equipment, which comprises: the supporting body 1 is provided with supporting plates A101 at the left end and the right end of the rear side of the top of the supporting body 1; a support plate B102 is arranged at the left end and the right end of the center position of the top of the support body 1; support plates C103 are arranged at the left end and the right end of the front side of the top of the support body 1; a motor 104 is arranged on the left side of the left support plate A101; a shearing frame 2 is arranged at the rear side of the support body 1; the top of the support body 1 is provided with an L-shaped guide plate 3; a driving shaft 105 is rotatably mounted on the support plate A101, and the left end of the driving shaft 105 is connected with an output shaft of the motor 104; the right end of the drive shaft 105 is provided with a gear a106; the shear frame 2 is provided with a mounting plate 201; the top of the mounting plate 201 is provided with a guide groove 202; an auxiliary straightening piece 203 is arranged inside the guide groove 202 in a sliding manner; the front side of the auxiliary straightening piece 203 is embedded with one end of a spring A204, and the other end of the spring A204 is embedded and installed on the front side of the guide groove 202; the left side and the right side of the auxiliary straightening piece 203 are provided with follow-up racks 205.

Wherein, the top end of the support plate B102 is rotatably provided with a follow-up shaft 107; the right end of the follow-up shaft 107 is provided with a gear B108, and the gear B108 is meshed with the gear A106; a synchronizing wheel A109 is arranged on the circumferential outer wall of the follow-up shaft 107; an extrusion wheel 1010 is arranged on the middle section of the follow-up shaft 107; the bottom of the support plate B102 is rotatably provided with a matching roller 1011; a guide shaft 1012 is rotatably arranged on the support plate C103;

the driving shaft 105 and the gear a106 are driven to rotate by the motor 104, the gear a106 drives the following shaft 107 and the extrusion wheel 1010 to rotate under the action of meshing with the gear B108, the extrusion wheel 1010 is enabled to be matched with the matching rollers 1011 to extrude the steel structural sheet in a first step through rotation, when the following shaft 107 rotates, the following shaft drives the upper guide shaft 1012 to rotate under the action of the synchronous wheel a109, the synchronous wheel B1013 and the corresponding synchronous belt, the guide shaft 1012 enables the two guide shafts 1012 to rotate relatively under the action of meshing of the two gears C1014, and the two guide shafts 1012 are enabled to be matched to guide the steel structural sheet.

Wherein, a synchronizing wheel B1013 is arranged at the right end of the upper guide shaft 1012, and the synchronizing wheel B1013 is connected with the synchronizing wheel A109 through a synchronous belt; the left end of the guide shaft 1012 is provided with a gear C1014, and the two gears C1014 are meshed and connected with each other; the top of the support body 1 is rotatably provided with a forming shaft 1015; a first bevel gear 1016 is arranged at the top end of the left forming shaft 1015; a third section of the forming shaft 1015 is provided with a synchronizing wheel C1017; a base forming roller 1018 is arranged on two third sections of the forming shaft 1015, and the base forming roller 1018 is in a conical structure;

the driving shaft 105 is driven to rotate by the motor 104, so that the driving shaft 105 drives the second bevel gear 1024 to rotate, in the rotating process, the second bevel gear 1024 drives the forming shaft 1015 positioned on the right side to rotate relatively under the meshing action of the first bevel gear 1016, the two forming shafts 1015 drive the base forming roller 1018 to rotate under the meshing action of the gear D1019, the two sides of the steel structure sheet are extruded by the base forming roller 1018, and the steel structure sheet is further formed on the basis of the first-step forming.

Wherein, three sections of the forming shaft 1015 are provided with gears D1019, and the two gears D1019 are engaged and connected; three sections of the forming shaft 1015 are also provided with a gear E1020, and the gear E1020 is positioned above the gear D1019; the gear E1020 is an incomplete gear, and the gear E1020 is meshed and connected with the follow-up rack 205; the top of the support body 1 is also rotatably provided with a driven shaft 1021, and the driven shaft 1021 is positioned at the rear side of the forming shaft 1015; a final forming roller 1022 is arranged on the circumferential outer wall of the driven shaft 1021; a synchronous wheel D1023 is arranged at the top end of the driven shaft 1021, and the synchronous wheel D1023 is connected with a synchronous wheel C1017 through a synchronous belt; a second bevel gear 1024 is arranged on the circumferential outer wall of the driving shaft 105, and the second bevel gear 1024 is meshed with the first bevel gear 1016;

when the two forming shafts 1015 rotate, the driven shaft 1021 and the final forming roller 1022 are driven to rotate under the action of the synchronous wheel C1017, the synchronous wheel D1023 and the corresponding synchronous belt, so that the final forming roller 1022 orients a steel sheet through rotation, meanwhile, the forming shafts 1015 drive the gear E1020 to rotate, the gear E1020 intermittently drives the follow-up rack 205 and the auxiliary straightening piece 203 to reciprocate back and forth along the guide groove 202 by utilizing the characteristic that the gear E is an incomplete gear and matching with the spring A204, and the auxiliary straightening piece 203 trims the shaped steel sheet entering the straightening groove 206 by utilizing the straightening groove 206.

Wherein, the auxiliary straightening piece 203 is provided with a straightening groove 206; the top of the auxiliary straightening piece 203 is slidably inserted with a shearing piece 207, and the bottom end of the shearing piece 207 is of an inclined structure; the top of the shearing part 207 is provided with a baffle plate 208; the bottom of the baffle 208 is embedded with one end of a spring B209, and the other end of the spring B209 is embedded and mounted at the top of the auxiliary straightening piece 203; a stress block 2010 is arranged at the top center of the baffle plate 208, and the top end of the stress block 2010 is in an inclined structure; an adjusting groove 2011 is formed in the rear side of the shearing frame 2; a sliding block 2012 is slidably mounted inside the adjusting groove 2011;

when the auxiliary straightening piece 203 moves, the inclined surface of the stress block 2010 is pushed by the inclined surface of the trigger block 2013, so that the stress block 2010 is stressed to drive the baffle 208 and the shearing piece 207 to descend, the shearing piece 207 descends, and the formed steel structure sheet is cut off.

The adjusting groove 2011 is provided with a triggering block 2013, and the bottom end of the triggering block 2013 is of an inclined structure; an adjusting screw 2014 is arranged on the right side of the shearing frame 2, and the left end of the adjusting screw 2014 is rotatably connected with the right side of the sliding block 2012;

the adjusting screw 2014 is manually rotated to drive the sliding block 2012 and the triggering block 2013 to move along the adjusting groove 2011, so that the triggering block 2013 is staggered with the stress block 2010, the stress block 2010 cannot be in contact with the triggering block 2013, and the cut-off function is closed;

in another embodiment: adjusting screw 2014 can replace for electric putter, can implement through electric putter indirectly to cutting of this device and open or close, compare in the manual work through more labour saving and time saving of adjusting screw 2014 manual control.

The specific use mode and function of the embodiment are as follows: when in use, firstly, the steel-structured sheet is inserted between two guide shafts 1012, then the motor 104 is started to drive the driving shaft 105 and the gear A106 to rotate by the motor 104, the gear A106 drives the following shaft 107 to rotate under the action of meshing with the gear B108, the upper guide shaft 1012 is driven to rotate under the action of the synchronizing wheel A109, the synchronizing wheel B1013 and the corresponding synchronous belt, the two guide shafts 1012 are relatively rotated under the action of meshing of the two gears C1014 by the guide shaft 1012, the two guide shafts 1012 are matched to guide the steel-structured sheet, meanwhile, the following shaft 107 also drives the extrusion wheel 1010 to rotate, the extrusion wheel 1010 is matched with the matching roller 1011 to extrude the steel-structured sheet for the first step, and when the driving shaft 105 is driven by the motor 104 to rotate, the driving shaft 105 drives the second bevel gear 1024 to rotate, and the second bevel gear 1024 rotates, the second bevel gear 1024 drives the forming shafts 1015 on the right to rotate relatively under the action of meshing with the first bevel gear 1016, so that the two forming shafts 1015 drive the base forming rollers 1018 to rotate under the action of meshing with the gear D1019, the base forming rollers 1018 extrude two sides of the steel sheet, the steel sheet is further formed on the basis of the first forming, the driven shaft 1021 and the final forming rollers 1022 are driven to rotate under the action of the synchronizing wheel C1017, the synchronizing wheel D1023 and the corresponding synchronizing belt while the two forming shafts 1015 rotate, the final forming rollers 1022 orient the steel sheet through rotation, the forming shaft 1015 drives the gear E1020 to rotate, the gear E1020 is matched with the spring a204 by utilizing the characteristic that the gear is an incomplete gear to drive the follow-up rack 205 and the auxiliary straightening piece 203 to reciprocate back and forth along the guide groove 202, and the auxiliary straightening piece 203 utilizes the straightening groove 206 to trim the shaped steel sheet entering the straightening groove 206, when the auxiliary straightening piece 203 moves, the inclined surface of the stress block 2010 is pushed by the inclined surface of the trigger block 2013, so that the stress block 2010 is stressed to drive the baffle 208 and the shearing piece 207 to descend, the shearing piece 207 descends, and the formed steel structure sheet is cut off.

The above description is intended to be illustrative of the present invention and not to limit the scope of the invention, which is defined by the claims appended hereto.

Claims

1. A support extrusion processing device for photovoltaic equipment, characterized by comprising: the supporting device comprises a supporting body (1), wherein supporting plates A (101) are arranged at the left end and the right end of the rear side of the top of the supporting body (1); a support plate B (102) is arranged at the left end and the right end of the center position of the top of the support body (1); support plates C (103) are arranged at the left end and the right end of the front side of the top of the support body (1); a motor (104) is arranged on the left side of the support plate A (101) on the left side; a shearing frame (2) is arranged on the rear side of the support body (1); the top of the support body (1) is provided with an L-shaped guide plate (3); a driving shaft (105) is rotatably mounted on the support plate A (101), and the left end of the driving shaft (105) is connected with an output shaft of a motor (104); a gear A (106) is arranged at the right end of the driving shaft (105); the shear frame (2) is provided with a mounting plate (201); the top of the mounting plate (201) is provided with a guide groove (202); an auxiliary straightening piece (203) is arranged in the guide groove (202) in a sliding manner; the front side of the auxiliary straightening piece (203) is embedded with one end of a spring A (204), and the other end of the spring A (204) is embedded and mounted on the front side of the guide groove (202); the left side and the right side of the auxiliary straightening piece (203) are provided with follow-up racks (205);

a follow-up shaft (107) is rotatably arranged at the top end of the support plate B (102); the right end of the follow-up shaft (107) is provided with a gear B (108), and the gear B (108) is meshed and connected with the gear A (106); a synchronous wheel A (109) is arranged on the circumferential outer wall of the follow-up shaft (107); an extrusion wheel (1010) is arranged on the middle section of the follow-up shaft (107); a matching roller (1011) is rotatably arranged at the bottom of the support plate B (102); a guide shaft (1012) is rotatably arranged on the support plate C (103); a synchronizing wheel B (1013) is arranged at the right end of the guide shaft (1012) above, and the synchronizing wheel B (1013) is connected with the synchronizing wheel A (109) through a synchronous belt; a gear C (1014) is arranged at the left end of the guide shaft (1012), and the two gears C (1014) are meshed and connected with each other; the top of the support body (1) is rotatably provided with a forming shaft (1015); a first bevel gear (1016) is arranged at the top end of the forming shaft (1015) on the left side; a synchronous wheel C (1017) is arranged on one third section of the forming shaft (1015); a base forming roller (1018) is arranged on two third sections of the forming shaft (1015), and the base forming roller (1018) is in a conical structure; three sections of the forming shaft (1015) are provided with gears D (1019), and the two gears D (1019) are meshed and connected; three sections of the forming shaft (1015) are also provided with a gear E (1020), and the gear E (1020) is positioned above the gear D (1019); the gear E (1020) is an incomplete gear, and the gear E (1020) is meshed and connected with the follow-up rack (205); the top of the support body (1) is also rotatably provided with a driven shaft (1021), and the driven shaft (1021) is positioned at the rear side of the forming shaft (1015); a final forming roller (1022) is arranged on the circumferential outer wall of the driven shaft (1021); a synchronous wheel D (1023) is arranged at the top end of the driven shaft (1021), and the synchronous wheel D (1023) is connected with the synchronous wheel C (1017) through a synchronous belt; a second bevel gear (1024) is arranged on the circumferential outer wall of the driving shaft (105), and the second bevel gear (1024) is meshed and connected with the first bevel gear (1016); a straightening groove (206) is formed in the auxiliary straightening piece (203); the top of the auxiliary straightening piece (203) is slidably inserted with a shearing piece (207), and the bottom of the shearing piece (207) is of an inclined structure; a baffle (208) is arranged at the top of the shearing part (207); the bottom of the baffle (208) is embedded with one end of a spring B (209), and the other end of the spring B (209) is embedded with the top of the auxiliary straightening piece (203).

2. The extrusion-processing apparatus of a photovoltaic device support according to claim 1, wherein: a stress block (2010) is arranged in the center of the top of the baffle (208), and the top end of the stress block (2010) is in an inclined structure; an adjusting groove (2011) is formed in the rear side of the shearing frame (2); and a sliding block (2012) is slidably mounted inside the adjusting groove (2011).

3. The support extrusion-processing apparatus for a photovoltaic device according to claim 2, wherein: a trigger block (2013) is arranged on the adjusting groove (2011), and the bottom end of the trigger block (2013) is of an inclined structure; the right side of shearing frame (2) is provided with accommodate the lead screw (2014), and the left end of accommodate the lead screw (2014) is connected with the right side rotation of sliding block (2012).