CN117583490B - Stainless steel kitchen ware stamping forming equipment and stamping forming method - Google Patents

Abstract

The invention relates to the technical field of kitchen ware stamping and discloses stainless steel kitchen ware stamping forming equipment and a stamping forming method, wherein the stainless steel kitchen ware stamping forming equipment comprises a main body and a stamping mechanism, the stamping mechanism is arranged at the top of the main body, a rotating frame is fixedly connected to the right side of the main body, a convex frame is fixedly connected to a middle shaft of the top of the main body, the stainless steel kitchen ware stamping forming equipment also comprises a positioning groove, the positioning groove is formed in one side, close to the rotating frame, of the convex frame, a turnover mechanism is arranged in the convex frame, the turnover mechanism comprises a servo motor, and the servo motor is fixedly connected to the left side of the convex frame. According to the invention, the arc spring is compressed backwards by extrusion force, so that the ejector block is contracted along with the track of the contraction groove through the arc strip, the ejector block is contracted to the top of the disc, the tooth block of the fixed point gear is separated from the gear after the ejector block reaches the position of the positioning groove, and meanwhile, the arc spring pushes the arc strip, so that the ejector block enters the inside of the positioning groove, the stability of the ejector block is improved, and the situation that the position of the ejector block is deviated during stamping is avoided.

Description

Stainless steel kitchen ware stamping forming equipment and stamping forming method

Technical Field

The invention relates to the technical field of kitchen ware stamping, in particular to stainless steel kitchen ware stamping forming equipment and a stamping forming method.

Background

Stainless steel is short for stainless acid-resistant steel, weak corrosion medium such as air, steam, water and the like or steel with stainless property is called stainless steel, steel with corrosion resistance of chemical corrosion medium (acid, alkali, salt and the like) is called acid-resistant steel, the corrosion resistance of the stainless steel is different due to the difference of chemical compositions, common stainless steel is generally not corrosion resistant of the chemical medium, the acid-resistant steel generally has the stainless property, the term "stainless steel" refers to not only one type of stainless steel but one hundred industrial stainless steels, and each type of developed stainless steel has good performance in specific application fields. The kitchen ware manufactured by the stainless steel material can play an excellent protective role on stored foods, has an excellent anti-striking performance, and is convenient for storing fluid foods, and in the production and processing process of the stainless steel kitchen ware, the kitchen ware is often processed in a stamping forming mode so as to improve the sealing performance and the storage capacity of the stainless steel kitchen ware.

When producing stainless steel kitchen utensils and appliances, need carry out stamping forming with the stainless steel sheet that cuts, but can lead to the phenomenon that the position of stainless steel sheet takes place to shift because of the inertia of transmission when transmitting the punching machine to the stainless steel sheet to lead to stamping forming failure, and need take out the stainless steel kitchen utensils and appliances that the punching press was accomplished again and put into stamping die after stamping forming and carry out the punching press, can be because in the time of taking out and putting into, the punching machine pauses the operation, thereby reduced the efficiency to stainless steel kitchen utensils and appliances stamping forming.

Disclosure of Invention

The invention aims to provide stainless steel kitchen ware stamping forming equipment and a stamping forming method, which are used for solving the problems in the background technology.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to a stainless steel kitchen ware stamping forming device and a stamping forming method, wherein the stainless steel kitchen ware stamping forming device comprises a main body and a stamping mechanism, the stamping mechanism is arranged at the top of the main body, a rotating frame is fixedly connected to the right side of the main body, a convex frame is fixedly connected to a center shaft of the top of the main body, and the stainless steel kitchen ware stamping forming device further comprises:

the positioning groove is formed in one side, close to the rotating frame, of the convex frame;

The turnover mechanism is arranged inside the convex frame and comprises a servo motor, the servo motor is fixedly connected to the left side of the convex frame, the output end of the servo motor is fixedly connected with a rotating rod, and the outer wall of the rotating rod is fixedly connected with a turnover block;

The pressing die mechanism is arranged at the top of the overturning block and comprises a sliding strip which is in sliding connection with the inside of the overturning block, the top of the sliding strip is fixedly connected with a lifting block, and the front surface of the lifting block is in threaded connection with the pressing die block;

The rotating mechanism is arranged at the top of the rotating frame and comprises a rotating column which is rotationally connected inside the rotating frame, the top of the rotating column is fixedly connected with a disc, and a plurality of shrinkage grooves are formed in the top of the disc;

The placing mechanism is arranged at the top of the disc and comprises an arc-shaped strip which is slidably connected inside the shrinkage groove, and a top block is fixedly connected to the top of the arc-shaped strip.

Further, four supporting legs are fixedly connected to the bottom of the main body, the four supporting legs are distributed at equal intervals, a rotary groove is formed in the top of the main body, and the outer wall of the disc is rotationally connected with the inner wall of the rotary groove.

Further, a transmission mechanism is arranged at one position of the bottom of the main body, which is close to the rotating frame, and comprises a placing frame, wherein the placing frame is fixedly connected to one position of the bottom of the main body, which is close to the rotating frame, a motor is fixedly connected to the top of the placing frame, a fixed point gear is fixedly connected to the output end of the motor, and the fixed point gear is rotationally connected with the top of the main body.

Further, the stamping mechanism comprises connecting legs, the connecting legs are fixedly connected to the top of the main body, a punching machine is fixedly connected to the top of the connecting legs, an output frame is fixedly connected to the front face of the punching machine, two stamping rods are connected to the inside of the output frame in a sliding mode, the two stamping rods are symmetrically distributed with the output frame as the center, pressing blocks are fixedly connected to one sides, opposite to the two stamping rods, of the two stamping rods, and the pressing blocks are correspondingly arranged at the center of the positioning groove.

Further, tilting mechanism still includes the spout, and the spout is seted up at the upset piece top, and the bull stick rotates to be connected inside the flange, and upset piece and constant head tank correspond the setting, and servo motor drives the bull stick and carries out reciprocating rotation, gear and fixed point gear engagement.

Further, the rotating mechanism further comprises a gear, the gear is fixedly connected to one end, far away from the disc, of the rotating column, the plurality of shrinkage grooves are formed in an arc shape by taking the disc as a central circumferential array.

Further, placing the mechanism still includes arc spring, arc spring fixed connection in arc strip left side, arc spring keep away from the one end of arc strip and shrink groove back wall fixed connection, arc spring has two, and two arc springs equidistance distributes, and the corresponding setting of arc strip shape and shrink groove, and the punching press groove has been seted up at kicking block top, and the briquetting sets up with the punching press groove is corresponding, and placing the mechanism has a plurality of, and a plurality of placing mechanism sets up with the shrink groove is corresponding.

Further, the pressing die mechanism further comprises springs, the springs are fixedly connected to one side, close to the overturning block, of the sliding strip, the two springs are symmetrically distributed by taking the sliding strip as a center, and one end, far away from the sliding strip, of the sliding strip is fixedly connected with the rear wall of the sliding groove.

A stainless steel kitchen ware stamping forming device and a forming method of the forming device comprise the following steps:

S1: after the equipment is stabilized on the ground through the supporting legs, a plurality of stainless steel sheets with fixed sizes are placed in a punching groove on a top block in advance, the positions of the stainless steel sheets are limited through the punching groove, a starting motor drives a fixed point gear to rotate, and a tooth block on the fixed point gear is meshed with the gear to drive a rotary column and a disc to rotate;

s2: the plurality of top blocks are moved to the positions of the positioning grooves through rotation of the disc, when the outer walls of the top blocks are contacted with the outer walls of the convex frames, the arc springs are compressed backwards through extrusion force, the top blocks shrink along with the tracks of the shrinkage grooves through the arc strips, the top blocks shrink to the tops of the disc, after the top blocks reach the positions of the positioning grooves, tooth blocks of the fixed-point gears are separated from the gears, and meanwhile the arc strips are pushed by the arc springs, so that the top blocks enter the inside of the positioning grooves;

s3: the method comprises the steps that a stamping die corresponding to a stamping groove is arranged on a lifting block in advance, when a top block with a stainless steel sheet enters the inside of a positioning groove, a servo motor is started to drive a rotating rod to rotate in a convex frame, so that a turnover block is driven to turn over, the outer wall of the turnover block is pressed against the outer wall of the top block, and meanwhile, the lifting block and the stamping block are driven to turn over to the position right above the stamping groove;

S4: the command is transmitted to the output frame through the punching machine, the punching rod is driven to punch through the transmission device inside the output frame, the pressing block is driven to punch the lifting block, the lifting block is driven to slide downwards in the sliding groove through the sliding bar compression spring, the pressing block is embedded with the punching groove, the punching of the stainless steel sheet is completed, after the pressing block rises, the spring can push the lifting block upwards, the pressing block leaves the punching groove, the finished product of the pressing block is convenient to leave the inside of the positioning groove, and after the punching of the stainless steel sheet on one pressing block is completed, the punching of the stainless steel sheet on the next pressing block can be continued.

The invention has the following beneficial effects:

According to the invention, after the equipment is stabilized on the ground through the supporting legs, a plurality of stainless steel sheets with fixed sizes are placed in the punching grooves on the jacking blocks in advance, the positions of the stainless steel sheets are limited through the punching grooves, so that the problem that the stainless steel sheets are in stamping forming failure due to deviation of the positions of the stainless steel sheets caused by inertia of transmission when the stainless steel sheets are transmitted to the lower parts of the pressing blocks is avoided, the fixed point gear is driven to rotate through the starting motor, the fixed point gear is meshed with the gear, the tooth blocks on the fixed point gear are meshed with the gear to drive the rotating column and the disc to rotate, the plurality of jacking blocks are moved to the positions of the positioning grooves through the rotation of the disc, when the outer walls of the jacking blocks are contacted with the outer walls of the convex frames, the arc springs are compressed backwards through extrusion force, the jacking blocks are contracted along with the tracks of the contraction grooves, the jacking blocks are contracted to the tops of the disc, and when the jacking blocks reach the positions of the positioning grooves, the arc blocks are separated from the gear, and meanwhile, the arc springs push the arc blocks to enter the inner parts of the positioning grooves, so that the jacking blocks are prevented from being in the position deviation when the jacking blocks are punched.

According to the invention, after the stainless steel sheet on one top block is stamped, the stainless steel sheet on the next top block can be stamped and formed continuously, and enough time is available for taking out the finished stainless steel kitchen ware product, then the stainless steel sheet is put in, and the stamping machine is prevented from stopping running in the time of taking out and putting in, so that the stamping and forming efficiency of the stainless steel kitchen ware is improved.

According to the invention, the stamping die corresponding to the stamping groove is arranged on the lifting block in advance, when the top block with the stainless steel sheet enters the positioning groove, the servo motor starts to drive the rotating rod to rotate in the convex frame, so that the turnover block is driven to turn over, the outer wall of the turnover block is propped against the outer wall of the top block, meanwhile, the lifting block and the pressing block are driven to turn over to the position right above the stamping groove, commands are transmitted to the output frame through the stamping machine, the stamping rod is driven to perform stamping motion through the transmission device in the output frame, the pressing block is driven to stamp the lifting block, so that the lifting block is driven to slide downwards in the sliding groove through the slide bar compression spring, the pressing module is embedded with the stamping groove, the stamping of the stainless steel sheet is completed, and after the pressing block ascends, the spring pushes the lifting block upwards, so that the pressing block leaves the stamping groove, the top block with a finished product is conveniently separated from the positioning groove, and the practicability of the device is improved.

Of course, it is not necessary for any one product to practice the invention to achieve all of the advantages set forth above at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is an overall exploded view of the present invention;

FIG. 3 is a schematic diagram of the main structure of the present invention;

FIG. 4 is a schematic view of a stamping mechanism according to the present invention;

FIG. 5 is a schematic view of a separating mechanism according to the present invention;

FIG. 6 is a schematic diagram of a transmission mechanism according to the present invention;

FIG. 7 is a schematic view of the placement mechanism of the present invention;

FIG. 8 is an enlarged view of FIG. 5 at A;

fig. 9 is a flow chart of the present invention.

In the drawings, the list of components represented by the various numbers is as follows:

In the figure: 1. a main body; 101. support legs; 102. a convex frame; 103. a positioning groove; 104. a rotary groove; 105. a rotating frame; 2. a transmission mechanism; 201. a placing rack; 202. a motor; 203. a fixed point gear; 3. a punching mechanism; 301. a connecting leg; 302. a punching machine; 303. an output rack; 304. punching a rod; 305. briquetting; 4. a turnover mechanism; 401. a servo motor; 402. a rotating rod; 403. a turnover block; 404. a chute; 5. a rotating mechanism; 501. a rotating column; 502. a gear; 503. a disc; 504. a shrink tank; 6. a placement mechanism; 601. an arc-shaped strip; 602. a top block; 603. an arc spring; 604. stamping a groove; 7. a compression molding mechanism; 701. a slide bar; 702. a lifting block; 703. pressing a module; 704. and (3) a spring.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

Referring to fig. 1-8, the invention discloses a stainless steel kitchen ware stamping forming device and a stamping forming method, comprising a main body 1, wherein a rotating frame 105 is fixedly connected to the right side of the main body 1, a convex frame 102 is fixedly connected to a center shaft at the top of the main body 1, and a positioning groove 103 is formed in the side, close to the rotating frame 105, of the convex frame 102, wherein the positioning groove 103 is formed;

The rotating mechanism 5 is arranged at the top of the rotating frame 105, the rotating mechanism 5 comprises a rotating column 501, the rotating column 501 is rotatably connected inside the rotating frame 105, a disc 503 is fixedly connected at the top of the rotating column 501, and a plurality of shrinkage grooves 504 are formed in the top of the disc 503;

the placing mechanism 6 is arranged at the top of the disc 503, the placing mechanism 6 comprises an arc-shaped strip 601, the arc-shaped strip 601 is slidably connected inside the shrinkage groove 504, a top block 602 is fixedly connected to the top of the arc-shaped strip 601, a plurality of stainless steel sheets with fixed sizes are placed inside a punching groove 604 on the top block 602, when the top block 602 reaches the position of the positioning groove 103, the tooth block of the fixed-point gear 203 is separated from the gear 502, and meanwhile, the arc-shaped spring 603 pushes the arc-shaped strip 601, so that the top block 602 enters the inside of the positioning groove 103, and the stability of the top block 602 is improved;

Four supporting legs 101 are fixedly connected to the bottom of the main body 1, the four supporting legs 101 are distributed at equal intervals, a rotary groove 104 is formed in the top of the main body 1, the outer wall of a disc 503 is rotationally connected with the inner wall of the rotary groove 104, and the equipment is stabilized on the ground through the supporting legs 101;

a transmission mechanism 2 is arranged at one position, close to the rotating frame 105, of the bottom of the main body 1, the transmission mechanism 2 comprises a placing frame 201, the placing frame 201 is fixedly connected to one position, close to the rotating frame 105, of the bottom of the main body 1, a motor 202 is fixedly connected to the top of the placing frame 201, a fixed point gear 203 is fixedly connected to the output end of the motor 202, the fixed point gear 203 is rotationally connected with the top of the main body 1, the fixed point gear 203 is driven to rotate by starting the motor 202, and a tooth block on the fixed point gear 203 is meshed with a gear 502 to drive a rotating column 501 and a disc 503 to rotate;

the rotating mechanism 5 further comprises a gear 502, the gear 502 is fixedly connected to one end, far away from the disc 503, of the rotating column 501, the plurality of shrinkage grooves 504 are arrayed circumferentially with the disc 503 as a center, the shrinkage grooves 504 are arc-shaped, and the plurality of top blocks 602 are moved to the positions of the positioning grooves 103 to move through rotation of the disc 503;

The placement mechanism 6 further comprises arc springs 603, the arc springs 603 are fixedly connected to the left side of the arc strips 601, one end, away from the arc strips 601, of each arc spring 603 is fixedly connected with the rear wall of the shrinkage groove 504, the two arc springs 603 are distributed equidistantly, the shape of each arc strip 601 is arranged corresponding to the corresponding shrinkage groove 504, a punching groove 604 is formed in the top of each ejector block 602, the positions of stainless steel sheets are limited through the punching grooves 604, the pressing blocks 305 are arranged corresponding to the punching grooves 604, the placement mechanism 6 is provided with a plurality of placement mechanisms 6, the placement mechanisms 6 are arranged corresponding to the shrinkage grooves 504, when the outer wall of each ejector block 602 contacts the outer wall of the convex frame 102, the arc springs 603 are compressed backwards through extrusion force, so that the ejector blocks 602 shrink along with the track of the shrinkage grooves 504 through the arc strips 601, and the ejector blocks 602 shrink to the tops of the discs 503.

When the stainless steel sheet stamping device is used, after the device is stabilized on the ground through the supporting legs 101, a plurality of stainless steel sheets with fixed sizes are placed in the stamping groove 604 on the top block 602 in advance, the positions of the stainless steel sheets are limited through the stamping groove 604, the situation that the stainless steel sheets are deformed due to the fact that the positions of the stainless steel sheets deviate due to inertia of transmission when the stainless steel sheets are transmitted to the lower part of the pressing block 305 is avoided, the fixed point gear 203 is driven to rotate through the starting motor 202, the fixed point gear 203 is meshed with the gear 502, the rotating column 501 and the disc 503 are driven to rotate after the tooth block on the fixed point gear 203 is meshed with the gear 502, the plurality of top blocks 602 are moved to the positions of the positioning groove 103 through the rotation of the disc 503, when the outer wall of the top block 602 is contacted with the outer wall of the protruding frame 102, the arc springs 603 are compressed backwards through the extrusion force, the top block 602 is contracted to the top of the disc 503 along with the track of the shrinkage groove 504, the arc springs 603 are separated from the gear 502 after the top block 602 reaches the position of the positioning groove 103, the tooth block 203, meanwhile, the arc springs 603 push the top block 103 to rotate with the gear 502, the arc springs 103 are pushed to move the top block 602 into the position of the steel sheets, the stainless steel sheets can be punched into the inner side of the stainless steel sheets, and the stainless steel sheets can be stamped out, and the stainless steel sheets can be continuously and punched and finished.

Example 2

Referring to fig. 1-8, the device further comprises a stamping mechanism 3, the stamping mechanism 3 is arranged at the top of the main body 1, the stamping mechanism 3 comprises a connecting leg 301, the connecting leg 301 is fixedly connected at the top of the main body 1, a stamping machine 302 is fixedly connected at the top of the connecting leg 301, an output frame 303 is fixedly connected at the front of the stamping machine 302, two stamping rods 304 are slidably connected inside the output frame 303, the two stamping rods 304 are symmetrically distributed by taking the output frame 303 as a center, a pressing block 305 is fixedly connected at one side opposite to the two stamping rods 304, the pressing block 305 is correspondingly arranged at the center of the positioning groove 103, commands are transmitted to the output frame 303 through the stamping machine 302, and a transmission device inside the output frame 303 drives the stamping rods 304 to perform stamping motion to drive the pressing block 305 to stamp the lifting block 702;

The turnover mechanism 4 is arranged inside the convex frame 102, the turnover mechanism 4 comprises a servo motor 401, the servo motor 401 is fixedly connected to the left side of the convex frame 102, the output end of the servo motor 401 is fixedly connected with a rotating rod 402, and the outer wall of the rotating rod 402 is fixedly connected with a turnover block 403;

the turnover mechanism 4 further comprises a sliding groove 404, the sliding groove 404 is formed in the top of the turnover block 403, the turnover block 403 is rotatably connected in the convex frame 102, the turnover block 403 is correspondingly arranged with the positioning groove 103, the servo motor 401 drives the turnover block 402 to reciprocally rotate, the gear 502 is meshed with the fixed point gear 203, when the top block 602 with a stainless steel sheet enters the positioning groove 103, the servo motor 401 starts to drive the turnover block 403 to rotate in the convex frame 102, and accordingly the outer wall of the turnover block 403 is driven to be pressed against the outer wall of the top block 602;

The pressing mechanism 7 is arranged at the top of the overturning block 403, the pressing mechanism 7 comprises a sliding bar 701, the sliding bar 701 is slidably connected inside the overturning block 403, the top of the sliding bar 701 is fixedly connected with a lifting block 702, the front surface of the lifting block 702 is in threaded connection with a pressing block 703, the outer wall of the overturning block 403 is abutted against the outer wall of the top block 602, and meanwhile, the lifting block 702 and the pressing block 703 are driven to overturn to the position right above the punching groove 604;

the pressing die mechanism 7 further comprises springs 704, the springs 704 are fixedly connected to one side, close to the overturning block 403, of the sliding bar 701, two springs 704 are symmetrically distributed by taking the sliding bar 701 as a center, one end, far away from the sliding bar 701, of the sliding bar 701 is fixedly connected with the rear wall of the sliding groove 404, the pressing block 305 is driven to punch the lifting block 702, accordingly, the lifting block 702 is driven to compress the springs 704 through the sliding bar 701 to slide downwards in the sliding groove 404, the pressing module 703 is enabled to be embedded with the punching groove 604, punching of stainless steel sheets is completed, after the pressing block 305 ascends, the springs 704 can push the lifting block 702 upwards, the pressing module 703 is enabled to leave the punching groove 604, and the finished jacking block 602 is enabled to leave the inside of the positioning groove 103 conveniently.

When the pressing device is used, a stamping die corresponding to the stamping groove 604 is arranged on the lifting block 702 in advance, after the top block 602 with a stainless steel sheet enters the inside of the positioning groove 103, the servo motor 401 can start to drive the rotating rod 402 to rotate in the inside of the convex frame 102, so that the turning block 403 is driven to turn over, the outer wall of the turning block 403 is pressed against the outer wall of the top block 602, meanwhile, the lifting block 702 and the pressing module 703 are driven to turn over to the position right above the stamping groove 604, a command is transmitted to the output frame 303 through the stamping machine 302, the pressing rod 304 is driven to perform stamping motion through a transmission device in the output frame 303, the pressing block 305 is driven to stamp the lifting block 702, the lifting block 702 is driven to slide downwards in the inside of the sliding groove 404 through the compression spring 704 of the sliding bar 701, the pressing module 703 is embedded with the stamping groove 604, the stainless steel sheet is stamped, and after the pressing block 305 is lifted, the spring 704 can push the lifting block 702 upwards, the pressing module 703 is separated from the stamping groove 604, and the top block 602 with a finished product is conveniently separated from the inside of the positioning groove 103.

A stainless steel kitchen ware stamping forming device and a forming method of the forming device comprise the following steps:

S1: after the equipment is stabilized on the ground through the supporting leg 101, a plurality of stainless steel sheets with fixed sizes are placed in a punching groove 604 on a top block 602 in advance, the positions of the stainless steel sheets are limited through the punching groove 604, a starting motor 202 drives a fixed point gear 203 to rotate, and through the engagement of the fixed point gear 203 and a gear 502, a tooth block on the fixed point gear 203 is engaged with the gear 502 and then drives a rotary column 501 and a disc 503 to rotate;

S2: through the rotation of the disc 503, a plurality of top blocks 602 are moved to the position of the positioning groove 103, when the outer wall of the top block 602 contacts the outer wall of the convex frame 102, the arc springs 603 are compressed backwards through extrusion force, the top block 602 is contracted along with the track of the contraction groove 504 through the arc strips 601, the top block 602 is contracted to the top of the disc 503, when the top block 602 reaches the position of the positioning groove 103, the tooth blocks of the fixed point gear 203 are separated from the gear 502, and meanwhile, the arc springs 603 push the arc strips 601, so that the top block 602 enters the positioning groove 103;

S3: a stamping die corresponding to the stamping groove 604 is arranged on the lifting block 702 in advance, when the top block 602 with a stainless steel sheet enters the positioning groove 103, the servo motor 401 starts to drive the rotating rod 402 to rotate in the convex frame 102, so that the turning block 403 is driven to turn over, the outer wall of the turning block 403 is pressed against the outer wall of the top block 602, and meanwhile, the lifting block 702 and the pressing module 703 are driven to turn over the stamping groove 604;

S4: the command is transmitted to the output frame 303 through the punching machine 302, the punching rod 304 is driven to carry out punching motion through the transmission device in the output frame 303, the pressing block 305 is driven to punch the lifting block 702, the lifting block 702 is driven to slide downwards in the sliding groove 404 through the sliding bar 701 and the compression spring 704, the pressing block 703 is embedded with the punching groove 604, the punching of stainless steel sheets is completed, after the pressing block 305 ascends, the spring 704 can push the lifting block 702 upwards, the pressing block 703 leaves the punching groove 604, the pressing block 602 with a finished product is convenient to leave the inside of the positioning groove 103, and after the punching of the stainless steel sheets on one pressing block 602 is completed, the punching molding of the stainless steel sheets on the next pressing block 602 can be continued.

The preferred embodiments of the invention disclosed above are intended only to assist in the explanation of the invention. The preferred embodiments are not exhaustive or to limit the invention to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best understand and utilize the invention. The invention is limited only by the claims and the full scope and equivalents thereof.

Claims (5)

1. The utility model provides a stainless steel kitchen utensils and appliances stamping forming equipment, includes main part (1) and stamping mechanism (3), stamping mechanism (3) set up at main part (1) top, main part (1) right side fixedly connected with revolving rack (105), main part (1) top axis department fixedly connected with flange (102), its characterized in that still includes:

The positioning groove (103) is formed in one side, close to the rotating frame (105), of the convex frame (102);

The turnover mechanism (4) is arranged inside the convex frame (102), the turnover mechanism (4) comprises a servo motor (401), the servo motor (401) is fixedly connected to the left side of the convex frame (102), the output end of the servo motor (401) is fixedly connected with a rotating rod (402), and the outer wall of the rotating rod (402) is fixedly connected with a turnover block (403);

The pressing mechanism (7), the pressing mechanism (7) is arranged at the top of the overturning block (403), the pressing mechanism (7) comprises a sliding bar (701), the sliding bar (701) is connected inside the overturning block (403) in a sliding way, the top of the sliding bar (701) is fixedly connected with a lifting block (702), and the front of the lifting block (702) is connected with a pressing module (703) in a threaded way;

The rotary mechanism (5), the rotary mechanism (5) is arranged at the top of the rotary frame (105), the rotary mechanism (5) comprises a rotary column (501), the rotary column (501) is rotationally connected inside the rotary frame (105), a disc (503) is fixedly connected at the top of the rotary column (501), and a plurality of shrinkage grooves (504) are formed in the top of the disc (503);

The placing mechanism (6), the placing mechanism (6) is arranged at the top of the disc (503), the placing mechanism (6) comprises an arc-shaped strip (601), the arc-shaped strip (601) is slidably connected inside the shrinkage groove (504), and a top block (602) is fixedly connected to the top of the arc-shaped strip (601);

The rotating mechanism (5) further comprises a gear (502), the gear (502) is fixedly connected to one end, far away from the disc (503), of the rotating column (501), a plurality of shrinkage grooves (504) are arrayed circumferentially with the disc (503) as a center, and the shrinkage grooves (504) are arc-shaped;

the turnover mechanism (4) further comprises a sliding groove (404), the sliding groove (404) is formed in the top of the turnover block (403), the rotating rod (402) is rotationally connected inside the convex frame (102), the turnover block (403) and the positioning groove (103) are correspondingly arranged, the servo motor (401) drives the rotating rod (402) to reciprocally rotate, and the gear (502) is meshed with the fixed-point gear (203);

The placing mechanism (6) further comprises arc springs (603), the arc springs (603) are fixedly connected to the left side of the arc strips (601), one end, far away from the arc strips (601), of each arc spring (603) is fixedly connected with the rear wall of the corresponding shrinkage groove (504), the number of the arc springs (603) is two, the shape of each arc strip (601) is corresponding to that of the corresponding shrinkage groove (504), the top of the top block (602) is provided with a stamping groove (604), pressing blocks (305) are corresponding to the stamping grooves (604), the placing mechanisms (6) are provided with a plurality of pressing blocks, and the placing mechanisms (6) are corresponding to the corresponding shrinkage grooves (504);

The compression molding mechanism (7) further comprises springs (704), the springs (704) are fixedly connected to one side, close to the overturning block (403), of the sliding strips (701), two springs (704) are symmetrically distributed by taking the sliding strips (701) as a center, and one end, far away from the sliding strips (701), of each spring (704) is fixedly connected with the rear wall of the corresponding sliding groove (404).

2. A stainless steel kitchen ware stamping forming apparatus as claimed in claim 1, wherein: four supporting legs (101) are fixedly connected to the bottom of the main body (1), the four supporting legs (101) are distributed at equal distances, a rotary groove (104) is formed in the top of the main body (1), and the outer wall of the disc (503) is rotationally connected with the inner wall of the rotary groove (104).

3. A stainless steel kitchen ware stamping forming apparatus as claimed in claim 2, wherein: the utility model discloses a rotary rack, including main part (1), main part (1) bottom is provided with drive mechanism (2) near a place of revolving rack (105), drive mechanism (2) are including rack (201), rack (201) fixed connection is near a place of revolving rack (105) in main part (1) bottom, rack (201) top fixedly connected with motor (202), motor (202) output fixedly connected with fixed point gear (203), fixed point gear (203) rotate with main part (1) top and be connected.

4. A stainless steel kitchen ware stamping forming apparatus as claimed in claim 3, wherein: the stamping mechanism (3) comprises connecting legs (301), the connecting legs (301) are fixedly connected to the top of the main body (1), stamping machines (302) are fixedly connected to the top of the connecting legs (301), output frames (303) are fixedly connected to the front faces of the stamping machines (302), two stamping rods (304) are connected to the inside of each output frame (303) in a sliding mode, the two stamping rods (304) are symmetrically distributed with the output frames (303) as the center, pressing blocks (305) are fixedly connected to one sides, opposite to the stamping rods (304), of the pressing blocks (305) and the center of the locating groove (103) are correspondingly arranged.

5. A stainless steel kitchen ware stamping forming apparatus as claimed in any one of claims 1 to 4, wherein the forming method of the forming apparatus comprises the steps of:

S1: after the equipment is stabilized on the ground through the supporting legs (101), a plurality of stainless steel sheets with fixed sizes are placed in a punching groove (604) on a top block (602) in advance, the positions of the stainless steel sheets are limited through the punching groove (604), a motor (202) is started to drive a fixed point gear (203) to rotate, the fixed point gear (203) is meshed with a gear (502), and a tooth block on the fixed point gear (203) is meshed with the gear (502) to drive a rotary column (501) and a disc (503) to rotate;

S2: through the rotation of the disc (503), a plurality of top blocks (602) are moved to the position of the positioning groove (103), when the outer wall of the top block (602) is contacted with the outer wall of the convex frame (102), the arc springs (603) are compressed backwards through extrusion force, the top blocks (602) shrink along with the track of the shrinkage groove (504) through the arc strips (601), the top blocks (602) shrink to the top of the disc (503), when the top blocks (602) reach the position of the positioning groove (103), the tooth blocks of the fixed-point gear (203) are separated from the gear (502), and meanwhile, the arc springs (603) push the arc strips (601) to enable the top blocks (602) to enter the inside of the positioning groove (103);

S3: a stamping die corresponding to a stamping groove (604) is arranged on a lifting block (702) in advance, when a top block (602) with a stainless steel sheet enters the inside of a positioning groove (103), a servo motor (401) can start to drive a rotating rod (402) to rotate in a convex frame (102), so that a turnover block (403) is driven to turn over, the outer wall of the turnover block (403) is pressed against the outer wall of the top block (602), and meanwhile, the lifting block (702) and a pressing block (703) are driven to turn over to the position right above the stamping groove (604);

S4: the command is transmitted to the output frame (303) through the punching machine (302), the punching rod (304) is driven to carry out punching motion through the transmission device in the output frame (303), the pressing block (305) is driven to punch the lifting block (702), so that the lifting block (702) is driven to slide downwards in the sliding groove (404) through the sliding bar (701) to compress the spring (704), the pressing block (703) is embedded with the punching groove (604), the stainless steel sheet is punched, after the pressing block (305) ascends, the spring (704) can push the lifting block (702) upwards, the pressing block (703) leaves the punching groove (604), the finished jacking block (602) is conveniently separated from the inside of the positioning groove (103), and after the stainless steel sheet on one jacking block (602) is punched, the stainless steel sheet on the next jacking block (602) can be continuously punched and formed.