CN111761261B - Efficient multi-plate synchronous positioning type cavity preparation process - Google Patents

Abstract

The invention relates to a high-efficiency multi-plate synchronous positioning type cavity preparation process, which comprises the following steps: cleaning the surfaces of the bottom plate, the left cavity plate, the right cavity plate and the rear cavity plate which are connected with the bottom plate; arranging the combined table in the middle of the bottom plate, and arranging positioning and clamping modules in three directions of the left cavity plate, the right cavity plate and the rear cavity plate; and (3) carrying out fixed positioning on the left cavity plate, the right cavity plate and the rear cavity plate: welding the connecting positions of the left cavity plate, the right cavity plate and the rear cavity plate and the connecting position of the left cavity plate, the right cavity plate and the rear cavity plate with the bottom plate; cleaning is carried out; dismantling the positioning and clamping module; the right cavity plate is provided with a hinge and is connected with the front cavity door. According to the invention, the required positioning plate body is firmly and synchronously positioned and welded through the setting of the combined positioning and clamping module, and the cavity preparation precision and the cavity preparation efficiency are ensured.

Description

Efficient multi-plate synchronous positioning type cavity preparation process

Technical Field

The invention relates to the technical field of machining, in particular to a high-efficiency multi-plate synchronous positioning type cavity preparation process.

Background

The cavity 100 shown in fig. 1 comprises a bottom plate 101, a left cavity plate 102, a right cavity plate 103 and a rear cavity plate 104 connected to the bottom plate 101, wherein the left side plate 102 is connected with a front cavity door 105 through a hinge in a rotating manner, the cavity 100 is processed by welding, the current stage welding mode is to correspondingly spot-weld positioning angle plates for positioning the left cavity plate 102, the right cavity plate 103 and the rear cavity plate 104 on the bottom plate 101, then the left cavity plate 102, the right cavity plate 103 and the rear cavity plate 104 are fixed on the positioning angle plates by spot welding, the joints of the left cavity plate 102, the right cavity plate 103 and the rear cavity plate 104 and the bottom plate 101 are welded, the current stage processing mode needs to prepare a plurality of positioning angle plates on site, the production resources are seriously wasted, the processing steps are complicated, meanwhile, the positioning angle plates are convenient to be removed, the positioning of the left cavity plate 102, the right cavity plate 103 and the rear cavity plate 104 cannot be firmly performed by spot welding mode, and the movement exists during welding, the welding precision cannot be guaranteed.

Therefore, it is necessary to provide an efficient process for manufacturing a cavity with multiple synchronously positioned plates to solve the above problems.

Disclosure of Invention

The invention aims to provide an efficient multi-plate synchronous positioning type cavity preparation process, which is characterized in that a positioning plate required by firm synchronous positioning welding is set through a combined positioning clamping module, and the cavity preparation precision and the preparation efficiency are ensured.

The technical scheme is as follows:

a high-efficiency multi-plate synchronous positioning type cavity preparation process comprises the following steps:

1) cleaning the surfaces of the bottom plate, the left cavity plate, the right cavity plate and the rear cavity plate which are connected with the bottom plate;

2) arranging the combined table in the middle of the bottom plate, and arranging positioning and clamping modules in three directions of the left cavity plate, the right cavity plate and the rear cavity plate;

3) and (3) carrying out fixed positioning on the left cavity plate, the right cavity plate and the rear cavity plate:

3-1) fixing the left cavity plate: the cylinder is extended to drive the fixed setting block to a fixed position, the rotating plate A is fixed, and the rotating plate B is rotationally adjusted to face the top end direction of the left cavity plate; the clamping module A and the clamping module B are driven to be relatively close to the left side edge and the top end edge of the clamping left cavity plate through a rotating knob, an adjusting gear and a rack on the sides of the rotating plate A and the rotating plate B respectively;

3-2) fixing the rear cavity plate: the cylinder is extended to drive the fixed setting block to a fixed position, and the rotating plate A and the rotating plate B are rotationally adjusted to face the top end direction of the rear cavity plate; the clamping module A and the clamping module B are driven to be relatively close to the top end edge of the clamping rear cavity plate through a rotating knob, an adjusting gear and a rack on the sides of the rotating plate A and the rotating plate B respectively;

3-3) fixing the right cavity plate: the cylinder is extended to drive the fixed setting block to a fixed position, the rotating plate B is fixed, and the rotating plate A is rotationally adjusted to face the top end direction of the right cavity plate; the clamping module A and the clamping module B are driven to be relatively close to the right side edge and the top end edge of the clamping right cavity plate through a rotating knob, an adjusting gear and a rack on the sides of the rotating plate A and the rotating plate B respectively;

4) welding the connecting positions of the left cavity plate, the right cavity plate and the rear cavity plate and the connecting position of the left cavity plate, the right cavity plate and the rear cavity plate with the bottom plate;

5) cleaning is carried out;

6) dismantling the positioning and clamping module;

7) the right cavity plate is provided with a hinge and is connected with the front cavity door.

Further, the step 2) is specifically as follows:

the embedded block of the positioning clamping module is inserted into the module embedded groove, and in the inserting process, the embedded block pushes the baffle plate to enter the embedded groove and then the baffle plate resets, so that the embedded block is prevented from being separated from the embedded groove and is matched with the module embedded groove to be positioned.

Further, the step 6) is specifically as follows:

the embedded block of the positioning clamping module is inserted into the module embedded groove, the embedded block is positioned between the bearing platform and the upper pressing platform of the module quick-release assembly, when a certain positioning clamping module is required to be released, the lower supporting plate and the upper pressing plate can be lifted through the lifting piece, and the rear lifting piece resets.

Further, the embedding block is a conical table body and is provided with an embedding plate pushing slope, the shape of the module embedding groove is consistent with that of the embedding block and is correspondingly provided with a baffle module, the baffle module comprises baffle telescopic groove plates correspondingly arranged on two sides of the module embedding groove, a baffle is connected in the telescopic groove of the baffle telescopic groove plates through an elastic body, and the top of the outer side of the baffle is provided with a baffle slope matched with the embedding plate pushing slope for use.

Further, the module breaks away from the subassembly fast and includes bottom plate and the top board that corresponds the setting, and bottom plate and top board correspond and are provided with bearing platform and last pressure platform, and bearing platform and last pressure platform all use with embedding piece phase-match and cooperation.

Further, clamping module A and clamping module B all include and press from both sides tight riser, connect in the tight diaphragm of the clamp that presss from both sides tight riser, rotate on pressing from both sides tight riser and be provided with the compact heap, press from both sides to correspond on the tight diaphragm and be provided with and press from both sides tight driving piece, and still be provided with the rotation platform on pressing from both sides tight riser, rotate the bench rotatable regulating plate that is used for adjusting laminating plate body edge direction that is provided with.

Furthermore, a reset torsion spring is arranged at the joint of the pressing block and the clamping vertical plate.

Compared with the prior art, the positioning plate body required by the combined positioning and clamping module is firmly and synchronously positioned and welded by setting the combined positioning and clamping module, and the cavity preparation precision and the cavity preparation efficiency are ensured.

Drawings

Fig. 1 is a schematic structural view of a chamber 100.

Fig. 2 is one of the structural schematic diagrams of the present invention.

FIG. 3 is a second schematic structural diagram of the present invention.

Fig. 4 is a third schematic structural diagram of the present invention.

FIG. 5 is a fourth schematic view of the present invention.

Detailed Description

Example (b):

referring to fig. 1 to 4, the present embodiment shows a module-combined multi-directional synchronous fixed processing structure, which includes a fixed-position convenient-adjustment processing structure, the fixed-position convenient-adjustment processing structure includes a fixed setting block 3, both sides of the fixed setting block 3 are provided with rotating connection assemblies 34, the rotating connection assemblies 34 disposed on both sides of the fixed setting block 3 are respectively provided with a rotating plate a32 and a rotating plate B31, both the rotating plate a32 and the rotating plate B31 are provided with adjusting sliding cavities 321, the adjusting sliding cavities 321 of the rotating plate a32 and the rotating plate B31 are respectively connected to a clamping setting plate a4 and a clamping setting plate B5 through a telescopic adjustment structure 8, the end portions of the clamping setting plate a4 and the clamping setting plate B5 are respectively provided with a clamping module a7 and a clamping module B6, both the clamping module a7 and the clamping module B6 include a clamping vertical plate 61, and a clamping horizontal plate 62 connected to the clamping vertical plate 61, the clamping vertical plate 61 is rotatably provided with a pressing block 63, the clamping horizontal plate 62 is correspondingly provided with a clamping driving part 64, the clamping vertical plate 61 is further provided with a rotating table 65, and the rotating table 65 is rotatably provided with an adjusting plate 66 for adjusting the edge direction of the attached plate body.

And a reset torsion spring is arranged at the joint of the pressing block 63 and the clamping vertical plate 61.

The telescopic adjusting structure 8 comprises an adjusting gear 81 arranged in the adjusting slide cavity 321, the adjusting gear 81 is connected with a rotating knob 82 through a connecting shaft 83, and racks 320 are arranged on the clamping setting plate A4 and the clamping setting plate B5 corresponding to the adjusting gear 81.

The rotation connection assembly 34 includes a rotating frame 341 connected to the fixed installation block 3, and a rotation shaft 342 provided on the rotating frame 341 for connecting the rotation plate a4 or the rotation plate B5.

The fixed setting block 3 has a plate body correcting table 33 at an end thereof for supporting the plate body.

The clamp drive 64 is formed by a butterfly screw with a fixed frustum at the end.

The fixed setting block 3 is connected to the extension block 2, and the extension block 2 is connected to the extension cylinder 1.

Fixed position convenient adjustment formula processing structure connects in the tight module 10 of positioning clamp, the tight module 10 of positioning clamp connects in the built-up table 9, be provided with a plurality of module embedded grooves 91 that are used for the tight module 10 embedding of positioning clamp on the built-up table 9, the tight module 10 of positioning clamp includes positioning setting piece 11, positioning setting piece 11 is connected with embedded piece 12, embedded piece 12 is the toper platform form and has the embedded plate and push away slope 121, the even and corresponding baffle module 13 that is provided with of module embedded groove 91 shape and embedded piece 12, baffle module 13 is including corresponding the flexible frid 131 of baffle that sets up in module embedded groove 91 both sides, the flexible inslot of baffle flexible frid 131 is connected with baffle 132 through elastomer 133, baffle 132 outside top is provided with pushes away the slope 134 of baffle that slope 121 cooperation was used with the embedded plate.

The elastic body 133 is constituted by a spring shaft.

The middle part of the assembly table 9 is provided with a module quick-release setting groove 92, and the module quick-release setting groove 92 is internally provided with a module quick-release component 15.

The module quick-release assembly 15 comprises a lower supporting plate 152 and an upper pressing plate 151 which are correspondingly arranged, a supporting platform 154 and an upper pressing platform 153 are correspondingly arranged on the lower supporting plate 152 and the upper pressing plate 151, and the supporting platform 154 and the upper pressing platform 153 are matched and matched with the embedded block 12.

The supporting table 152 and the upper pressing table 151 are connected by a connecting body 150, and the supporting table 152 is connected to the lifting member 14.

The lifting member 14 is constituted by a hydraulic cylinder.

The embodiment is used for preparing the cavity 100, and the specific process flow is as follows:

1) cleaning the surfaces of the base plate 101, the left cavity plate 102, the right cavity plate 103 and the rear cavity plate 104 connected to the base plate 101;

2) arranging a combined table 9 in the middle of a bottom plate 101, and arranging a positioning and clamping module 10 in three directions of a left cavity plate 102, a right cavity plate 103 and a rear cavity plate 104;

3) fixing and positioning the left cavity plate 102, the right cavity plate 103 and the rear cavity plate 104:

3-1) securing the left cavity plate 102: the extension cylinder 1 is driven to drive the fixed setting block to a fixed position, the rotating plate A32 is fixed, and the rotating plate B31 is adjusted to rotate to the direction towards the top end of the left cavity plate 102; the clamping module A7 and the clamping module B6 are driven by the rotating knob 82, the adjusting gear 81 and the rack 320 on the rotating plate A32 and the rotating plate B31 to clamp the left side edge and the top end edge of the left cavity plate 102 respectively;

3-2) securing the back cavity plate 104: the extension cylinder 1 is driven to drive the fixed setting block to a fixed position, and the rotating plate A32 and the rotating plate B31 are adjusted to rotate to the direction towards the top end of the rear cavity plate 104; the top end edge of the rear cavity plate 104 is clamped by the clamping module A7 and the clamping module B6 which are driven by the rotating knob 82, the adjusting gear 81 and the rack 320 on the sides of the rotating plate A32 and the rotating plate B31 respectively;

3-3) securing the right cavity plate 103: the extension cylinder 1 is driven to drive the fixed setting block to a fixed position, the rotating plate B31 is fixed, and the rotating plate A32 is adjusted to rotate to the direction towards the top end of the right cavity plate 103; the right side edge and the top end edge of the right cavity plate 103 are clamped by a clamping module A7 and a clamping module B6 which are driven by a rotating knob 82, an adjusting gear 81 and a rack 320 on the sides of a rotating plate A32 and a rotating plate B31 respectively;

4) welding the joint of the left cavity plate 102, the right cavity plate 103 and the rear cavity plate 104 and the joint of the bottom plate 101;

5) cleaning is carried out;

6) dismantling the positioning and clamping module 10;

7) a hinge is provided on the right cavity plate 103 and connects to the front cavity door 105.

Meanwhile, the fixing module can be independently used, such as:

setting the required fixed number of modularization, wherein the setting process is as follows: selecting an embedded groove 91 needing to be set with the positioning and clamping module 10, inserting the embedded block 12 of the positioning and clamping module 10 into the module embedded groove 91, and in the inserting process, pushing the baffle 132 away by the embedded block 12 to enter the embedded groove 91 and then resetting the baffle 132 to form the functions of stopping the embedded block 12 from coming out and positioning by matching with the module embedded groove 91; after the insertion, the insertion block 12 is located between the supporting platform 154 and the upper pressing platform 153, and when a certain positioning and clamping module 10 needs to be removed, the lower supporting plate 152 and the upper pressing plate 151 are lifted by the lifting piece 14, and then the lifting piece 14 is reset.

Simultaneously, the independent use of the modular combination is another display mode of the scheme, such as:

the fixed flow is as follows: extension cylinder 1 drive, drive fixed setting block to needs fixed plate position, to the required fixed position of plate body, rotation adjustment rotor plate A32 and rotor plate B31, respectively through the rotation knob 82 of rotor plate A32 and rotor plate B31 side, adjusting gear 81, rack 320 drives and presss from both sides tight module A7 and presss from both sides tight module B6 and is close to the clamp plate body relatively, when pressing from both sides tightly, adjusting plate 66 can be according to the better laminating plate body of plate body edge shape adjustment angle, it compresses tightly the plate body to press from both sides tight driving piece 64 and drive the compact heap.

Compared with the prior art, the invention can quickly adjust the fixing position aiming at plate bodies with different shapes, thereby ensuring the welding efficiency.

What has been described above are merely some embodiments of the present invention. It will be apparent to those skilled in the art that various changes and modifications can be made without departing from the inventive concept thereof, and these changes and modifications can be made without departing from the spirit and scope of the invention.

Claims (6)

1. A high-efficiency multi-plate synchronous positioning type cavity preparation process is characterized by comprising the following steps of: the method comprises the following steps:

1) cleaning the surfaces of the bottom plate, the left cavity plate, the right cavity plate and the rear cavity plate which are connected with the bottom plate;

2) arranging the combined table in the middle of the bottom plate, and arranging positioning and clamping modules in three directions of the left cavity plate, the right cavity plate and the rear cavity plate;

the positioning and clamping module is connected to the combination table, the fixed-position convenient and adjustable machining structure is connected to the positioning and clamping module and comprises a fixed setting block, and rotating connection assemblies are arranged on two sides of the fixed setting block; the fixed setting block is connected with the lengthening block, and the lengthening block is connected with the extension cylinder; the rotating connecting assembly comprises a rotating frame connected with the fixed setting block and a rotating shaft arranged on the rotating frame and used for connecting the rotating plate A or the rotating plate B; the rotating connecting components arranged on both sides of the fixed setting block are respectively provided with a rotating plate A and a rotating plate B; the adjusting sliding cavities of the rotating plate A and the rotating plate B are respectively connected with a clamping setting plate A and a clamping setting plate B through a telescopic adjusting structure; the end parts of the clamping setting plate A and the clamping setting plate B are respectively provided with a clamping module A and a clamping module B; the telescopic adjusting structure comprises an adjusting gear arranged in the adjusting sliding cavity, the adjusting gear is connected with the rotating knob through a connecting shaft, and racks are arranged on the sides of the clamping setting plate A and the clamping setting plate B corresponding to the adjusting gear;

3) and (3) carrying out fixed positioning on the left cavity plate, the right cavity plate and the rear cavity plate:

3-1) fixing the left cavity plate: the cylinder is extended to drive the fixed setting block to a fixed position, the rotating plate A is fixed, and the rotating plate B is rotationally adjusted to face the top end direction of the left cavity plate; the clamping module A and the clamping module B are driven to be relatively close to the left side edge and the top end edge of the clamping left cavity plate through a rotating knob, an adjusting gear and a rack on the sides of the rotating plate A and the rotating plate B respectively;

3-2) fixing the rear cavity plate: the cylinder is extended to drive the fixed setting block to a fixed position, and the rotating plate A and the rotating plate B are rotationally adjusted to face the top end direction of the rear cavity plate; the clamping module A and the clamping module B are driven to be relatively close to the top end edge of the clamping rear cavity plate through a rotating knob, an adjusting gear and a rack on the sides of the rotating plate A and the rotating plate B respectively;

3-3) fixing the right cavity plate: the cylinder is extended to drive the fixed setting block to a fixed position, the rotating plate B is fixed, and the rotating plate A is rotationally adjusted to face the top end direction of the right cavity plate; the clamping module A and the clamping module B are driven to be relatively close to the right side edge and the top end edge of the clamping right cavity plate through a rotating knob, an adjusting gear and a rack on the sides of the rotating plate A and the rotating plate B respectively;

4) welding the connecting positions of the left cavity plate, the right cavity plate and the rear cavity plate and the connecting position of the left cavity plate, the right cavity plate and the rear cavity plate with the bottom plate;

5) cleaning is carried out;

6) dismantling the positioning and clamping module;

7) the right cavity plate is provided with a hinge and is connected with the front cavity door.

2. The process for preparing the efficient multi-plate synchronous positioning type cavity according to claim 1, wherein the process comprises the following steps:

the combined table is provided with a plurality of module embedded grooves used for embedding the positioning and clamping modules, each positioning and clamping module comprises a positioning and setting block, each positioning and setting block is connected with an embedded block, each embedded block and each module embedded groove are correspondingly arranged, and each module embedded groove is consistent in shape with the embedded block and is correspondingly provided with a baffle module comprising a baffle;

wherein, the step 2) is specifically as follows:

the embedded block of the positioning clamping module is inserted into the module embedded groove, and in the inserting process, the embedded block pushes the baffle to enter the embedded groove and then the baffle resets, so that the embedded block is prevented from being separated and matched with the module embedded groove to be positioned.

3. The process for preparing the efficient multi-plate synchronous positioning type cavity according to claim 2, wherein the process comprises the following steps:

the middle part of the combined table is provided with a module quick-detachment setting groove, a module quick-detachment assembly is arranged in the module quick-detachment setting groove, the module quick-detachment assembly comprises a lower supporting plate and an upper pressing plate which are correspondingly arranged, a bearing table and an upper pressing table are correspondingly arranged on the lower supporting plate and the upper pressing plate, the bearing table and the upper pressing table are matched and matched with the embedded block for use, the bearing table and the upper pressing table are connected through a connector, and the bearing table is connected to the lifting piece;

wherein, the step 6) is specifically as follows:

the embedded block of the positioning clamping module is inserted into the module embedded groove, the embedded block is positioned between the bearing platform and the upper pressing platform of the module quick-release assembly, the module quick-release assembly is positioned in the middle of the combined platform, when the certain positioning clamping module is required to be released, the lower supporting plate and the upper pressing plate are lifted by the lifting piece, and then the lifting piece is reset.

4. The process for preparing the efficient multi-plate synchronous positioning cavity according to any one of claims 2 to 3, wherein: the embedded block is in a conical table body shape and is provided with an embedded plate push-away slope, the shape of the module embedded groove is consistent with that of the embedded block and is correspondingly provided with a baffle module, the baffle module comprises baffle telescopic groove plates correspondingly arranged on two sides of the module embedded groove, a baffle is connected in a telescopic groove of the baffle telescopic groove plates through an elastic body, and the top of the outer side of the baffle is provided with a baffle slope matched with the embedded plate push-away slope for use.

5. The process for preparing the efficient multi-plate synchronous positioning type cavity according to claim 4, wherein the process comprises the following steps: the clamping module A and the clamping module B are connected to a clamping transverse plate of the clamping vertical plate, a pressing block is arranged on the clamping vertical plate in a rotating mode, a clamping driving piece is correspondingly arranged on the clamping transverse plate, a rotating table is further arranged on the clamping vertical plate, and an adjusting plate used for adjusting the edge direction of the attaching plate body is rotatably arranged on the rotating table.

6. The process for preparing the efficient multi-plate synchronous positioning type cavity according to claim 5, wherein the process comprises the following steps: and a reset torsion spring is arranged at the joint of the pressing block and the clamping vertical plate.

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