CN215090133U - Stamping device for integrated aluminum substrate of radiation system - Google Patents

Abstract

The utility model relates to a stamping device for aluminium base board of integral type of radiation system, which comprises a frame, go up the mould subassembly, the lower mould subassembly, it includes mould power spare to go up the mould subassembly, go up the mould lifter plate, the cope match-plate pattern, stamping module and punching press power spare, it can drive the mould lifter plate and go up and down to go up mould power spare, punching press power spare can drive stamping module and go up and down, the lower mould subassembly includes the die holder, the lower bolster, the push rod, push rod driving piece and ejector pad, the punching press lug has been seted up on the lower bolster, a plurality of through-holes that run through the lower bolster have evenly been seted up on the lower bolster, be provided with the ejector pad in the through-hole, the guide rail has been seted up to the lower bolster bottom, the push rod sets up in the guide rail and supports the ejector pad, the push rod driving piece is connected with the push rod. The utility model discloses degree of automation is high, and machining efficiency is high, can be automatically with aluminium base board continuous stamping be special shape, can be so that the radiant tube can adopt multiple coil pipe mode and aluminium base board cooperation installation, for laying of furred ceiling radiant panel provides convenience, greatly reduced workman's intensity of labour.

Description

Stamping device for integrated aluminum substrate of radiation system

Technical Field

The utility model relates to a radiation plate processing technology field especially relates to a stamping device for aluminium base board of integral type of radiation system.

Background

The radiation plate has become popular due to its features of energy saving, comfort, no occupation of room area, etc. However, the conventional aluminum substrate is generally of a flat plate structure, and the radiant tube is mounted on the aluminum substrate and is not easy to position and fix when being mounted in a matching manner, so that the overall structure is complex and the volume is large.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an automatic degree is high, machining efficiency is high, the good stamping device who is used for the aluminium base board of integral type of radiation system of formability.

The utility model discloses a realize through following technical scheme: a stamping device for an integrated aluminum substrate of a radiation system comprises a rack, and an upper die assembly and a lower die assembly which are arranged on the rack, wherein the upper die assembly comprises an upper die power piece, an upper die lifting plate, an upper die plate, a plurality of groups of stamping modules and a stamping power piece, the upper die plate is fixed at the bottom end of the upper die lifting plate, the upper die power piece is connected with the upper die lifting plate and can drive the upper die lifting plate to lift, the stamping module is arranged on the upper die plate, the stamping power piece is connected with the stamping module and can drive the stamping module to lift along the upper die plate, the lower die assembly is correspondingly arranged below the upper die assembly and comprises a lower die base, a lower die plate, a push rod driving piece and a push block, the lower die plate is fixed on the lower die base, stamping lugs which are embedded with the stamping modules are arranged on the lower die plate, and a plurality of through holes which penetrate through the lower die plate are uniformly arranged on the lower die plate, the push rod driving part is connected with the push rod, and the push rod driving part can drive the push rod to move along the guide rail, so that each push block is jacked upwards along the through hole.

In order to guarantee the continuous stamping forming of product, the utility model discloses carry out special design to last mould, the stamping module on the cope match-plate pattern includes a plurality of horizontal ribs that parallel, and the both ends of two adjacent horizontal ribs link to each other through the arc piece, and each horizontal rib and arc piece enclose into a plurality of oval notches and arc notch, arc notch symmetry sets up at oval notch both ends. And the transverse ribs and the arc-shaped blocks are arranged in a split mode and can be respectively stamped.

Further, in order to facilitate the later assembly of the aluminum substrate, the arc-shaped blocks are provided with convex cylinders.

Further, in order to ensure that the distance between every two steps is the same in the aluminum plate stepping production process, a raised punching needle is arranged in the arc-shaped notch, and a pilot hole can be punched.

In order to realize the jacking for the convenience of drive ejector pad, a plurality of direction notches have been seted up on the push rod, the ejector pad sets up in the guide slot mouth, the guide slot mouth includes bottom horizontal direction mouth, oblique direction mouth and top horizontal direction mouth, and when the push rod removed, the ejector pad realized the jacking by bottom horizontal direction mouth along oblique direction mouth rebound entering horizontal direction mouth.

In order to further improve the production efficiency and avoid manual work participation, the stamping device further comprises a traction assembly, the traction assembly is correspondingly arranged on one side of the lower die assembly and comprises a bottom plate, a sliding seat, a pair of sliding seats, a pushing power piece, a moving plate, a pressing block and a pressing block driving piece, the sliding seats are symmetrically arranged on two sides of the bottom plate, the sliding seats are respectively and slidably connected with the sliding block, the pushing power piece is connected with the sliding block and can push the sliding block to move along the sliding seat, the moving plate is fixed at the top end of the sliding block, the pressing blocks are arranged at two ends of the moving plate symmetrically, the pressing block driving piece is connected with the pressing block, and the pressing block driving piece can drive the pressing block to overturn so as to compress or loosen an aluminum substrate on the moving plate.

In order to ensure the stability of the aluminum substrate in the moving process, the pushing power parts are a pair, and the two pushing power parts are connected with the two sliding blocks through the connecting plate.

In order to facilitate the positioning of the aluminum substrate during the stamping process, a plurality of side positioning blocks are arranged on one side of the bottom plate.

In order to press the aluminum substrate tightly, supporting blocks for supporting the aluminum substrate are correspondingly arranged below the pressing block, and pressing channels are formed between the pressing block and the supporting blocks.

The utility model has the advantages that: this a stamping device for aluminium base board of integral type of radiation system degree of automation is high, and machining efficiency is high, can be automatically be special shape with aluminium base board continuous punching press, can be so that the radiant tube can adopt multiple coil pipe mode and aluminium base board cooperation installation, provides convenience for laying of furred ceiling radiation board, greatly reduced workman's intensity of labour.

Drawings

Fig. 1 is a schematic perspective view of a stamping device for an integrated aluminum substrate of a radiation system according to the present invention;

fig. 2 is a side view of the stamping apparatus for an integrated aluminum substrate of a radiation system of the present invention;

fig. 3 is a schematic structural view of the upper plate of the present invention;

fig. 4 is a schematic structural view of the lower die assembly of the present invention;

fig. 5 is a schematic perspective view of the traction assembly of the present invention;

FIG. 6 is a side view of the draft assembly of the present invention;

fig. 7 is a schematic view of a three-dimensional structure of an integrated aluminum substrate according to the present invention.

Detailed Description

The following detailed description of the preferred embodiments of the present invention will be provided in conjunction with the accompanying drawings, so that the advantages and features of the present invention can be more easily understood by those skilled in the art, and the protection scope of the present invention can be clearly and clearly defined. In the present invention, directional terms such as "up", "down", "front", "back", "left", "right", "top", "bottom", etc. refer to directions of the attached drawings only. Accordingly, the directional terms used are used for describing and understanding the present invention, and are not used for limiting the present invention.

As shown in fig. 1 and 2, the stamping device for the integrated aluminum substrate of the radiation system includes a frame 1, and an upper die assembly 2, a lower die assembly 3, and a traction assembly 4 disposed on the frame 1.

Go up the mould subassembly and include mould power piece 21, go up mould lifter plate 22, cope match-plate pattern 23, punching press power piece 24 and punching press module, cope match-plate pattern 23 is fixed in last mould lifter plate 22 bottom, it is connected and can drive the lift of last mould lifter plate 22 to go up mould power piece 21 and last mould lifter plate 22, punching press module sets up the cope match-plate pattern bottom, punching press power piece 24 is many sets, and punching press power piece 24 can drive each punching press module respectively and go up and down along cope match-plate pattern 23.

As shown in fig. 3, the upper die plate 23 is provided with a stamping module, specifically, the upper die plate 23 is provided with a plurality of parallel transverse ribs 231, two ends of two adjacent transverse ribs 231 are connected through an arc block 232, each transverse rib 231 and arc block 232 enclose a plurality of oval notches and arc notches, the arc notches are symmetrically arranged at two ends of the oval notches, the arc block 232 is provided with a raised cylinder 234, a raised stamping pin 235 is arranged in each arc notch, one side of each transverse rib 231 is further provided with an independent rib 233, and the ribs 233 are parallel to the transverse ribs 231 and have the same length. It should be noted that the ribs 233, the transverse ribs 231 and the arc-shaped blocks 232 are arranged in a split manner, and are driven by different stamping power parts respectively, and are stamped sequentially and continuously from front to back.

As shown in fig. 4, the lower mold assembly is correspondingly disposed below the upper mold assembly, and includes a lower mold base, a lower mold plate 31, a push rod 33, a push rod driving member 32, and a push block 34. The lower template 31 is fixed on the lower die holder, and the lower template 31 is provided with a stamping lug which is embedded with a stamping module on the upper template, specifically, the stamping lug comprises a plurality of oval lugs 311 and semi-circular lugs 312 which are correspondingly arranged at two ends of the oval lugs 311, the oval lugs 311 can be embedded into the oval grooves of the upper template, the semi-circular lugs 312 can be embedded into the arc grooves of the upper template, a plurality of grooves are formed between the oval lugs 311 and the semi-circular lugs 312, transverse ribs, ribs and arc blocks of the upper template can be embedded into the grooves, in addition, grooves 313 are formed in the grooves, cylinders of the upper template can be inserted into the grooves 313, through holes 314 are formed in the semi-circular lugs 312, and stamping needles of the upper template can be inserted into the through holes 314. Evenly set up a plurality of through-holes 315 that run through lower bolster 31 on the lower bolster 31, be provided with ejector pad 34 in the through-hole respectively, a plurality of guide rails 316 that parallel have been seted up to lower bolster 31 bottom, and each guide rail 316 corresponds and sets up in through-hole 315 below, push rod 33 sets up in guide rail 316 and supports ejector pad 34, has seted up a plurality of guide slot 331 on the push rod 33, ejector pad 34 sets up in guide slot 331, guide slot 331 includes bottom horizontal direction mouth, oblique direction mouth and top horizontal direction mouth, and when push rod 33 removed, ejector pad 34 was gone up along oblique direction mouth rebound entering horizontal direction mouth by bottom horizontal direction mouth and is realized the jacking, push rod driving piece 32 is connected with push rod 33, and push rod driving piece 32 can drive push rod 33 and remove along guide rail 316 to make each ejector pad 34 along through-hole 315 jacking.

As shown in fig. 5 and 6, the traction assembly is correspondingly arranged on one side of the lower die assembly, and includes a bottom plate 41, sliding seats 43, sliders 44, two pushing power members 45, a moving plate 47, a pressing block 48 and a pressing block driving member 49, a plurality of side positioning blocks 42 are arranged on one side of the bottom plate 41, the sliding seats 43 are symmetrically arranged on two sides of the bottom plate 41, the sliders 44 are respectively connected in the sliding seats 43 in a sliding manner, the two pushing power members 45 are connected with the two sliders 44 through a connecting plate 46, the pushing power members 45 can push the sliders 44 to move along the sliding seats 43, the moving plate 47 is fixed at the top ends of the sliders 44, the pressing blocks 48 are symmetrically arranged at two ends of the moving plate 47, the pressing block driving member 49 is connected with the pressing block 48, a supporting block 410 for supporting an aluminum substrate is correspondingly arranged below the pressing block 48, a pressing channel 411 is formed between the pressing block 48 and the supporting block 410, the pressing block driving piece 49 can drive the pressing block 48 to overturn so as to press or loosen the aluminum substrate on the moving plate 47.

Referring to fig. 1-6, during processing, a flat aluminum substrate is fed onto the lower die plate 31 from an upper station, the aluminum substrate abuts against the side positioning blocks 42 to realize positioning, the upper die power component 21 drives the upper die plate 23 to descend integrally, the upper die plate 23 descends to a fixed position, the punching power component 24 drives the punching pins 235 to descend first, guide holes can be punched, the intervals of subsequent punching are ensured to be the same, one-time punching is completed, the punching power component 24 drives the ribs 233 to descend, one-time punching is completed, the punching power component 24 drives the transverse ribs 231 to descend, one-time punching is completed, the punching power component 24 drives the three sets of arc blocks 232 without the cylinders 234 to descend, one-time punching is completed, and after one-time punching is completed, the push rod driving component 32 drives the push blocks 34 to lift the punched aluminum substrate away from the lower die plate 31, the pushing power part 45 pushes the moving plate 47 to extend forwards, so that the aluminum substrate is supported by the supporting block 410 on the moving plate 47, at this time, the pressing block driving part 49 drives the pressing block 48 to turn over and press the aluminum substrate on the moving plate 47, the pushing power part 45 pushes the moving plate 47 to move backwards, so that the next punching is performed, and the punching power part 24 sequentially drives each group of punching modules to descend, so that the continuous stepping punch forming is completed. As shown in fig. 7, the molded aluminum substrate 5 has grooves 51 and protrusions 52 formed on its surface in a crisscross pattern.

It should be noted that, in the present invention, the power member, the driving member, etc. may be an oil cylinder, an air cylinder, a motor, etc. to realize the motion through a connecting rod, a connecting shaft, etc., and are not limited to the structure in the specification and the drawings attached to the specification.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention.

Claims (9)

1. A stamping device for an integrated aluminum substrate of a radiation system is characterized in that: the stamping device comprises a rack, and an upper die assembly and a lower die assembly which are arranged on the rack, wherein the upper die assembly comprises an upper die power part, an upper die lifting plate, an upper die plate, a stamping module and a stamping power part, the upper die plate is fixed at the bottom end of the upper die lifting plate, the upper die power part is connected with the upper die lifting plate and can drive the upper die lifting plate to lift, the stamping module is arranged on the upper die plate, the stamping power part is connected with the stamping module and can drive the stamping module to lift along the upper die plate, the lower die assembly is correspondingly arranged below the upper die assembly and comprises a lower die holder, a lower die plate, a push rod driving part and a push block, the lower die plate is fixed on the lower die holder, a stamping lug which is embedded with the stamping module is arranged on the lower die plate, a plurality of through holes which penetrate through the lower die plate are uniformly arranged on the lower die plate, the push blocks are respectively arranged in the through holes, and a plurality of parallel guide rails are arranged at the bottom end of the lower die plate, and each guide rail is correspondingly arranged below the through hole, the push rod is arranged in the guide rail and supports the push block, the push rod driving part is connected with the push rod, and the push rod driving part can drive the push rod to move along the guide rail, so that each push block is jacked upwards along the through hole.

2. The stamping device for an integral aluminum base plate of a radiation system as claimed in claim 1, wherein: the stamping module comprises a plurality of parallel transverse ribs, two ends of every two adjacent transverse ribs are connected through arc blocks, each transverse rib and each arc block enclose a plurality of oval notches and arc notches, and the arc notches are symmetrically arranged at two ends of each oval notch.

3. The stamping device for an integral aluminum base plate of a radiation system as claimed in claim 2, wherein: the arc-shaped block is provided with a raised cylinder.

4. The stamping device for an integral aluminum base plate of a radiation system as claimed in claim 2, wherein: and a raised punching needle is arranged in the arc-shaped notch.

5. The stamping device for an integral aluminum base plate of a radiation system as claimed in claim 1, wherein: the push rod is provided with a plurality of guide notches, the push block is arranged in the guide notches, each guide notch comprises a bottom horizontal guide opening, an inclined guide opening and a top horizontal guide opening, and when the push rod moves, the push block moves upwards along the inclined guide openings through the bottom horizontal guide openings to enter the horizontal guide openings to realize jacking.

6. The stamping device for an integral aluminum base plate of a radiation system as claimed in claim 1, wherein: the punching device further comprises a traction assembly, the traction assembly is correspondingly arranged on one side of the lower die assembly and comprises a bottom plate, a pair of sliding seats, sliders, pushing power pieces, a movable plate, pressing blocks and pressing block driving pieces, the sliding seats are symmetrically arranged on two sides of the bottom plate, the sliders are respectively and slidably connected in the sliding seats and are connected with the sliders, the pushing power pieces can push the sliders to move along the sliding seats, the movable plate is fixed to the top ends of the sliders, the pressing blocks are symmetrically arranged at two ends of the movable plate, the pressing block driving pieces are connected with the pressing blocks, and the pressing block driving pieces can drive the pressing blocks to overturn so as to compress or loosen an aluminum substrate on the movable plate.

7. The stamping device for an integral aluminum base plate of a radiation system as claimed in claim 6, wherein: the two pushing power parts are connected with the two sliding blocks through a connecting plate.

8. The stamping device for an integral aluminum base plate of a radiation system as claimed in claim 6, wherein: and a plurality of side positioning blocks are arranged on one side of the bottom plate.

9. The stamping device for an integral aluminum base plate of a radiation system as claimed in claim 6, wherein: supporting blocks for supporting the aluminum substrate are correspondingly arranged below the pressing block, and a pressing channel is formed between the pressing block and the supporting blocks.

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