CN113427261A

CN113427261A - High-efficient syntonizer manufacturing installation

Info

Publication number: CN113427261A
Application number: CN202110777652.6A
Authority: CN
Inventors: 陈康; 吴群仙; 徐天云; 徐兴华
Original assignee: Jinhua Troq Electronic Co ltd
Current assignee: Jinhua Troq Electronic Co ltd
Priority date: 2021-07-09
Filing date: 2021-07-09
Publication date: 2021-09-24
Anticipated expiration: 2041-07-09
Also published as: CN113427261B

Abstract

The invention discloses a high-efficiency resonator manufacturing device which comprises a base and a stamping part, wherein the stamping part is arranged on the base and used for stamping a plate material to form pins of a resonator, a distribution mechanism used for moving and overturning the pins after stamping is arranged below the base, and the stamping part slides up and down to drive the distribution mechanism to operate. The automatic collecting and separating turnover mechanism solves the problems that pins are automatically collected and automatically separated and turned over after stamping is finished, and preparation is made for the next automatic clamping process, so that the collection of materials after stamping and the automatic turnover are automatically carried out in the next working process, automation is realized, the probability of errors of human factors is effectively eliminated, the production efficiency is improved, and the labor cost is reduced.

Description

High-efficient syntonizer manufacturing installation

Technical Field

The invention relates to the technical field of resonator manufacturing equipment, in particular to an efficient resonator manufacturing device.

Background

The resonator mainly consists of the following parts: input, output electrode, bias voltage electrode, vibration dish, anchor structure, substrate and control circuit, and input, the last generally welding of output electrode has the stitch, and present welding is all accomplished by manual welding, and need pass through the unloading from the stitch welding to on the point machine, transportation, clamping, a series of loaded down with trivial details processes of welding, and need the transport of circulation many times in whole flow, just so produced very big amount of labour, need use a large amount of personnel, manufacturing cost is high at all times.

Disclosure of Invention

The invention provides a high-efficiency resonator manufacturing device aiming at the defects in the prior art.

In order to solve the technical problems, the invention is solved by the following technical scheme: the utility model provides a high-efficient syntonizer manufacturing installation, includes base and punching press portion, the punching press portion sets up on the base for the stitch of sheet material punching press formation syntonizer, the base below is provided with the branch transport mechanism that is used for moving the stitch that the punching press was accomplished the upset, the operation of branch transport mechanism is driven in the upper and lower slip of punching press portion.

The blanking device has the beneficial effects that after the punching blanking is completed, the materials are separated and turned over.

In the above scheme, preferably, the base includes a guide rod and a die cavity plate, the stamping part includes a stamping power component and a stamping sliding plate, the stamping sliding plate is slidably disposed on the guide rod, the stamping power component is disposed at the top end of the base and connected with the stamping sliding plate to provide power for the stamping sliding plate to slide up and down, a punch is disposed at the bottom of the stamping sliding plate, and a stamping hole matched with the punch is disposed on the die cavity plate.

In the above scheme, it is preferred, divide fortune mechanism to include that slip rack device, head rod, second connecting rod, first turning block, stitch collect piece and spout piece, the spout piece sets up the below at the die cavity board, and is provided with first cavity between the two, the stitch is collected the piece and is slided and set up in first cavity, and respectively is provided with one about and, set up the recess that holds the stitch in the middle of the stitch is collected the piece, and one end is provided with the upset piece, the one end of head rod and second connecting rod sets up respectively on the upset piece of controlling two stitch collection pieces, and the other end sets up on the slip rack device, slip rack device slides from top to bottom and drives the stitch collection piece horizontal slip.

The stamping rack device has the beneficial effects that the finished product materials after stamping can enter the pin collecting block, and the sliding rack device slides up and down to drive the pin collecting block to slide left and right.

In the above scheme, preferably, the chute block is provided with a second chute for turning over the stitch collecting block and a first chute for limiting the first steering block, the sliding rack device comprises a lifting rod, a first rack, a second elastic part and a first guide rod, the sliding rack device is arranged on a bottom plate of the chute block through the first guide rod in a sliding manner, the first guide rod is provided with the second elastic part, the lifting rod is arranged on the die cavity plate in a sliding manner, the top end of the lifting rod is matched with the stamping sliding plate, the first steering block is provided with a first gear, the sliding rack device comprises a first rack, the first rack is matched with the first gear, and the first rack can slide up and down to drive the first gear to rotate so as to drive the first steering block to rotate.

The sliding rack device has the advantages that the sliding rack device slides up and down to drive the first steering block to rotate, so that when the stamping sliding plate moves downwards, the sliding rack device drives the first steering block to rotate upwards to drive the pin collecting block to slide upwards, when the stamping sliding plate moves upwards, the sliding rack device drives the first steering block to rotate downwards, a support on the second sliding groove position disappears, and when the pin collecting block slides outwards to the second sliding groove position, the sliding rack device can automatically turn over.

In the above scheme, preferably, the first connecting rod and the second connecting rod can be produced when being subjected to tensile force, and return to the initial state when the tensile force disappears.

The dead point problem of the mechanism in the operation process is solved, so that the mechanism can normally operate.

The invention has the beneficial effects that: the automatic collecting and separating turnover mechanism solves the problems that pins are automatically collected and automatically separated and turned over after stamping is finished, and preparation is made for the next automatic clamping process, so that the collection of materials after stamping and the automatic turnover are automatically carried out in the next working process, automation is realized, the probability of errors of human factors is effectively eliminated, the production efficiency is improved, and the labor cost is reduced.

Drawings

FIG. 1 is a schematic view of the present invention.

Fig. 2 is a schematic view of the distribution mechanism of the present invention.

Fig. 3 is a schematic view of the internal components of the distribution mechanism of the present invention.

FIG. 4 is a schematic view of a runner block of the present invention.

FIG. 5 is a cross-sectional view of a first connecting rod and a second connecting rod of the present invention.

FIG. 6 is a schematic view of a clamping device of the present invention.

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

Fig. 8 is a partial cross-sectional view of the feed mechanism of the present invention.

FIG. 9 is a schematic view of the automatic clamping mechanism of the present invention.

Detailed Description

The invention is described in further detail below with reference to the following detailed description and accompanying drawings:

example 1:

referring to fig. 1-5, a high-efficiency resonator manufacturing device comprises a base 1, a stamping part 3 and a separating and transporting mechanism 4, wherein the base 1 comprises a die cavity plate 12, an upper top plate 13 and a lower bottom surface 14, the die cavity plate 12 and the upper top plate 13 are provided with a plurality of guide rods 11, the stamping part 3 comprises a stamping power part 31, a stamping sliding plate 32, a shifting tooth combination 35 and a linkage plate 33, the stamping sliding plate 32 is slidably arranged on the guide rods 11, the stamping power part 31 is arranged at the top end of the base 1, and a telescopic rod of the stamping power part is connected with the stamping sliding plate 32, wherein the stamping power part provides power for the stamping sliding plate 32 to slide up and down, a punch 34 is arranged at the bottom of the stamping sliding plate 32, and a stamping hole 122 is arranged on the die cavity plate 12 in a matching manner, wherein the resonator is of a double-pin design, so that 2 punches 34 and stamping holes 122 are arranged in the device.

The separating and transporting mechanism 4 comprises a sliding rack device 41, a first connecting rod 42, a second connecting rod 43, a first turning block 44, a stitch collecting block 45 and a sliding groove block 46, the sliding groove block 46 is arranged on the lower bottom surface of the die cavity plate 12, a first cavity is formed between the sliding groove block 46 and the die cavity plate 12, the sliding groove block 46 is provided with a first sliding groove 461, a second sliding groove 462 and a blanking hole 463, the first turning block 44 comprises a first gear 441, a rotating shaft 442, a blocking block 443 and a limiting block 444, the first turning block 44 is rotatably arranged on a wrapping plate outside the sliding groove block 46 through the rotating shaft 442, a resetting block 443 of the first turning block is arranged on the second sliding groove 462, the limiting block 444 is arranged on the first sliding groove 461 and used for upper limiting, a groove for accommodating stitches is arranged in the middle of the stitch collecting block 45, a turning piece 451 is arranged at one end of the stitch collecting block 45, and the stitch collecting block 45 is slidably arranged in the first cavity, one end of each of the first connecting rod 42 and the second connecting rod 43 is rotatably disposed on the turning member 451 of the left pin collecting block 45 and the other end is rotatably disposed on the sliding rack device 41, the sliding rack device 41 includes a lifting rod 411, a first rack 412, a second elastic member 416 and a first guide rod 413, the first rack 412 is disposed on the left and the right and is respectively matched with a first gear 441 on the left and the right first turning block 44, the first rack 412 can slide up and down to drive the first gear 441 to rotate so as to drive the first turning block 44 to rotate, the sliding rack device 41 is slidably disposed on the bottom plate of the sliding groove block 46 through the first guide rod 413, the first guide rod 413 is provided with the second elastic member 416, two ends of the second elastic member 416 respectively contact the bottom plate of the sliding groove block 46 and the transverse plate of the sliding rack device 41, the lifting rod 411 is slidably disposed on the cavity plate 12, and the top end of the lifting rod is disposed in cooperation with the punch slide plate 32.

The first connecting rod 42 comprises a first connecting rod upper section 421, a first connecting rod lower section 422 and a first connecting rod elastic piece 423, wherein the first connecting rod upper section 421 is slidably arranged in the first connecting rod lower section 422, and the first connecting rod elastic piece 423 is arranged between the first connecting rod upper section 421 and the first connecting rod lower section 422, so that the first connecting rod upper section can be extended when receiving tensile force, and can be restored to an initial state when the tensile force disappears, and can not be shortened when being subjected to pressure under the initial state.

The second connecting rod 43 includes a second connecting rod upper section 431, a second connecting rod lower section 432, and a second connecting rod elastic member 433, the second connecting rod upper section 431 is slidably disposed in the second connecting rod lower section 432, and the second connecting rod elastic member 433 is disposed therebetween, so that the second connecting rod upper section 431 can be extended when receiving a tensile force, and is restored to an initial state when the tensile force disappears, and does not shorten when receiving a pressure in the initial state.

Wherein, in the initial state, the pin collecting block 45 is located on the second sliding groove 462 and vertically faces downwards, the state at this time is that the punched pins are vertically sent downwards to the next process, at this time, the punching sliding plate 32 slides downwards, the bottom surface of the punching sliding plate abuts against the lifting rod 411, so that the sliding rack device 41 slides downwards, the first rack 412 on the sliding rack device 41 drives the first gear 441 to rotate, so that the first turning block 44 rotates upwards, the pin collecting block 45 abuts against in the rotating process, so that the pin collecting block 45 slides upwards around the center of the turnover part, and finally the pin collecting block is in a horizontal state, when the sliding rack device 41 slides downwards, one rotation fulcrum of the first connecting rod 42 and the second connecting rod 43 slides downwards, and the side surface of the pin collecting block 45 presses against the side surface of the second sliding groove 462, so that a horizontal limiting force is applied, so that the other rotation fulcrum is not moved, therefore, the first connecting rod 42 and the second connecting rod 43 extend, when the stitch collecting blocks 45 are in a horizontal state, the horizontal limit disappears, so that under the action of the second connecting rod elastic member 433 and the first connecting rod elastic member 423, the two stitch collecting blocks 45 get close to the middle, and finally when the first connecting rod 42 and the second connecting rod 43 return to the initial state, the groove in the middle of the stitch collecting block 45 faces the punching hole 122, so that the punched stitches fall into the groove in the middle of the stitch collecting blocks 45.

After the punching is completed, the punching sliding plate 32 slides upwards, so that the pressure on the lifting rod 411 disappears, the sliding rack device 41 slides upwards under the action of the second elastic member 416, one end of the first connecting rod 42 and the second connecting rod 43 moves upwards during the sliding process, so as to push the other end of the first connecting rod to slide outwards, so that the stitch collecting block 45 slides outwards and slides to the position of the second sliding groove 462, the first turning block 44 rotates downwards under the action of the first rack 412 when the sliding rack device 41 slides upwards, and when the stitch collecting block 45 slides to the position of the second sliding groove 462, no top contact exists below the stitch collecting block, so that the stitch collecting block rotates downwards under the action of self gravity, and finally, the stitches collected in the grooves vertically downwards fall into the next process through the blanking holes 463.

Example 2:

referring to fig. 1-9, a high-efficiency resonator manufacturing device comprises a base 1, a stamping part 3, a welding mechanism 7, a feeding mechanism 6, a separating and conveying mechanism 4, a conveying mechanism 5 and a clamping device 5, wherein the base 1 comprises a die cavity plate 12, an upper top plate 13 and a lower bottom surface 14, the die cavity plate 12 and the upper top plate 13 are provided with a plurality of guide rods 11, the stamping part 3 comprises a stamping power part 31, a stamping sliding plate 32, a shifting tooth combination 35 and a linkage plate 33, the stamping sliding plate 32 is slidably arranged on the guide rods 11, the stamping power part 31 is arranged at the top end of the base 1, and telescopic rods thereof are connected with the stamping sliding plate 32, wherein the stamping power part provides up-and-down sliding power for the stamping sliding plate 32, a stamping head 34 is arranged at the bottom of the stamping sliding plate 32, and stamping holes 122 are cooperatively arranged on the die cavity plate 12, wherein the resonator is of a double-pin design, thus, 2 punches 34 and punch holes 122 are provided in the device.

The shifting tooth assembly 35 is arranged on the side surface of the stamping sliding plate 32 and comprises a shifting tooth 351, a shifting tooth chamber 352 and a second elastic member 353, the shifting tooth 351 is arranged in a right triangle shape, the bottom of the shifting tooth 351 is rotatably arranged on the shifting tooth chamber 352, the right-angle side of the shifting tooth 351 is in a horizontal state in an initial state, the second elastic member 353 is arranged between the shifting tooth 351 and the shifting tooth chamber 352 and can rotate the whole shifting tooth 351 inwards to enter the shifting tooth chamber 352 to compress the second elastic member 353, the punching and feeding mechanism 6 comprises a ratchet wheel 61, a roller 62 and an automatic clamping mechanism 63, the die cavity plate 12 is provided with a long slot hole 121, the roller 62 is arranged in the long slot hole 121 in a unidirectional rotation manner, the surface of the roller 62 is slightly higher than the upper plane of the die cavity plate 12, wherein the outer surface of the roller is provided with anti-slip texture which can bring a dynamic pressure to move when rotating, the ratchet wheel 61 is arranged at one end of the roller, and the ratchet wheel 61 is matched with the shifting tooth combination 35.

When the punching sliding plate 32 slides downwards, the shifting tooth combination 35 is driven to slide downwards, the oblique edge of the shifting tooth 351 is in top contact with the ratchet wheel 61, the ratchet wheel 61 is arranged on the roller 62, and the roller 62 is arranged in a one-way rotating mode, so that the ratchet wheel 61 does not rotate when in top contact, the shifting tooth 351 rotates towards the shifting tooth chamber 352, the second elastic piece 353 is pressed and contacted, when the shifting tooth 351 slides downwards across the teeth on the ratchet wheel 61, the pressing contact force on the shifting tooth 351 disappears, the initial position is recovered under the action of the second elastic piece 353, at the moment, the punching sliding plate 32 starts to slide upwards, the shifting tooth 351 drives the ratchet wheel 61 to rotate, and therefore, the plate can be automatically fed after each punching is finished.

The automatic clamping mechanism 63 includes a pressing shaft 631, a first elastic member 632 and a guide bracket 633, the guide bracket 633 is disposed on the cavity plate 12, the pressing shaft 631 is slidably disposed on the guide bracket 633, and both ends of the pressing shaft 631 are provided with limit collars, wherein when the pressing sliding plate 32 slides downward, the lower bottom surface of the pressing sliding plate 32 presses and contacts the upper end of the pressing shaft 631, so that the pressing sliding plate slides downward to press the plate, so that the plate cannot move in the pressing process, and when the pressing sliding plate 32 slides upward, the pressing state is released, thereby facilitating automatic feeding of the plate.

The conveying mechanism 5 is arranged on the lower bottom surface 14, the conveying mechanism 5 is provided with a plurality of clamping devices 5, the distance between every two clamping devices 5 is the same, and the conveying mechanism 5 is provided with a sensor, so that when the conveying mechanism 5 moves every time, the clamping devices 5 above the conveying mechanism can all correspond to the blanking points of the distribution mechanism 4.

The lower end of the sliding rack device 41 is further provided with a locking plate 414, the clamping device 5 comprises a clamping block 52, an unlocking plate 54, a clamp base 53 and a belt press-contact switch 55, the clamp base 53 is provided with a guide ring 51 which plays a role in guiding pins when the pins fall off, the belt press-contact switch 55 is arranged on the clamp base 53 and is positioned below the unlocking plate 54, one clamping block 52 is arranged on each pin left and right, the clamping block 52 comprises a clamping block guide rod 521 and is arranged on the clamp base 53 in a sliding mode through the clamping block guide rod 521, a limiting groove 524 is formed in the clamping block guide rod 521, a positioning block 523 is arranged at the front end of the clamping block guide rod 521, a groove matched with the pins is formed in the positioning block 523, a clamping elastic part 57 is arranged on the clamping block guide rod 521, two ends of the clamping elastic part are in top contact with the positioning block 523 and the clamp base 53, and the unlocking plate 54 comprises an unlocking push rod 541, a push rod, The unlocking guide rod 542 and the unlocking clamping plate 543, the unlocking plate 54 is slidably disposed on the clamp base 53 through the unlocking guide rod 542, the unlocking guide rod 542 is provided with the reset elastic piece 56, two ends of the unlocking guide rod are respectively abutted to the unlocking clamping plate 543 and the clamp base 53, when the unlocking guide rod 542 is in an initial state, the unlocking clamping plate 543 is clamped on the limiting groove 524 of the clamping block 52, and the unlocking push rod 541 is disposed in cooperation with the locking plate 414.

Wherein each time the punch slide plate 32 moves upwards to the highest point, the punched pins in the distribution mechanism 4 fall onto the clamping device 5, when the punch slide plate 32 slides downward, the lock plate 414 in the transport mechanism 4 abuts the unlocking push rod 541, so that the unlocking plate 54 slides downwards, the unlocking clamping plate 543 thereon slides out of the limiting groove 524 on the clamping block guide rod 521, so that the clamping block 52 clamps the pins under the action of the clamping elastic piece 57, and presses the belt press-contact switch 55 in the descending process, when the stamping sliding plate 32 moves upwards, the unlocking push rod 541 is disconnected from the locking plate 414, the unlocking plate 54 moves upwards for a certain distance to be disconnected from pressing the belt press touch switch 55, at the moment, the conveying mechanism 5 starts to rotate, the next clamping device 5 is driven to slide to the position below the blanking point of the sub-conveying mechanism 4, and the clamping device 5 in the clamping state flows into the next station.

Welding mechanism 7 includes welder 71 and welder sliding base 72, welder 71 slides and sets up on welder sliding base 72, and welder 71 top is provided with gyro wheel 74, be provided with welder elastic component 73 between welder 71 bottom plate and the rifle sliding base 72, welder 71 is located the below of linkage plate 33, linkage plate 33 can press the gyro wheel 74 on the welder 71 to the gliding kinetic energy.

When the stamping sliding plate 32 slides downwards, the lower bottom surface of the linkage plate 33 on the stamping sliding plate presses and contacts the roller 74 on the welding mechanism 7, so that the welding gun 71 starts to be electrified and works, the welding gun slides into a working position along the inclined hole of the welding gun sliding base 72 to weld pins, when the stamping sliding plate 32 slides upwards, the welding gun 71 returns to an initial state under the action of the welding gun elastic piece 73, and the welding gun is powered off and stops working after the roller 74 is separated from the linkage plate 33.

The working principle or the using method is as follows:

after the sheet material is placed on the cavity plate 12, the power supply is started, the punch slide plate 32 slides downwards to drive the shifting tooth combination 35 to slide downwards, the inclined edge of the shifting tooth 351 abuts against the ratchet wheel 61, because the ratchet wheel 61 is arranged on the roller 62, and the roller 62 is arranged in a unidirectional rotation manner, the ratchet wheel 61 does not rotate when the inclined edge abuts against the ratchet wheel, the shifting tooth 351 rotates towards the shifting tooth chamber 352 to press and contact the second elastic member 353, when the shifting tooth 351 slides downwards across the tooth on the ratchet wheel 61, the pressing and contacting force on the shifting tooth 351 disappears, and the initial position is recovered under the action of the second elastic member 353,

at the moment, the stamping operation is completed, the stamping sliding plate 32 starts to slide upwards, the shifting teeth 351 drive the ratchet wheel 61 to rotate, and the ratchet wheel 61 rotates to drive the roller 62 to rotate, so that the purpose of automatically feeding the plate after each stamping is completed is achieved.

And the stamping sliding plate 32 slides downwards, the lower bottom surface of the stamping sliding plate 32 presses and contacts the upper end of the pressing shaft 631, so that the stamping sliding plate slides downwards to press the plate, the plate cannot move in the stamping process, and when the stamping sliding plate 32 slides upwards, the pressing state is released, and the automatic feeding of the plate is facilitated.

When the punching sliding plate 32 does not slide downwards, and the punching sliding plate 32 is at the initial position, the stitch collecting block 45 is located on the second sliding groove 462 and vertically downwards, in this case, the last punched stitch is vertically and downwards fed into the next process, at this time, the punching sliding plate 32 slides downwards, the bottom surface thereof abuts against the lifting rod 411, so that the sliding rack device 41 slides downwards, the first rack 412 on the sliding rack device 41 drives the first gear 441 to rotate, so that the first turning block 44 rotates upwards, the stitch collecting block 45 is abutted during the rotation process, so that the stitch collecting block 45 slides upwards around the center of the turnover part, and finally the stitch collecting block is in the horizontal state, when the sliding rack device 41 slides downwards, one rotation fulcrum of the first connecting rod 42 and the second connecting rod 43 slides downwards, and the side surface of the stitch collecting block 45 is pressed against the side surface of the second sliding groove 462, therefore, a horizontal limiting force is applied, so that the other rotation pivot is not moved, the first connecting rod 42 and the second connecting rod 43 are extended, when the stitch collecting block 45 is in a horizontal state, the horizontal limiting is eliminated, so that under the action of the second link elastic member 433 and the first link elastic member 423, the two stitch collecting blocks 45 are drawn towards the middle, and finally, when the first connecting rod 42 and the second connecting rod 43 return to the initial state, the groove in the middle of the stitch collecting block 45 faces the punching hole 122, so that the punched stitches fall into the groove in the middle of the stitch collecting block 45.

When the stamping sliding plate 32 moves upwards to the highest point each time, pins stamped in the separating and conveying mechanism 4 fall onto the clamping devices 5, when the stamping sliding plate 32 slides downwards, the locking plate 414 is pressed against the unlocking push rod 541, the unlocking plate 54 slides downwards, the unlocking clamping plate 543 on the unlocking plate is made to slide out of the limiting groove 524 on the clamping block guide rod 521, the pins are clamped by the clamping block 52 under the action of the clamping elastic piece 57, the belt press-contact switch 55 is pressed in the descending process, when the stamping sliding plate 32 moves upwards, the unlocking push rod 541 is disconnected from the locking plate 414, the unlocking plate 54 moves upwards to a certain extent and is separated from the press-contact switch 55, because the conveying mechanism 5 is provided with a plurality of clamping devices 5, and the distance between each clamping device 5 is the same, after the separation and the press, the conveying mechanism 5 starts to rotate, and drives the next clamping device 5 to slide to the blanking point of the separating and conveying mechanism 4, due to the sensor arranged on the conveying mechanism 5, after the next clamping device 5 moves to the blanking point, the conveying mechanism 5 stops rotating, and the clamping device 5 in the clamping state flows into the next station.

When the stamping sliding plate 32 slides downwards, the welding mechanism 7 on the next station is pressed on the roller 74 on the welding mechanism 7 by the lower bottom surface of the linkage plate 33 on the stamping sliding plate, so that the welding gun 71 starts to be electrified and works, the welding gun slides into a working position along the inclined hole of the welding gun sliding base 72 to weld pins, when the stamping sliding plate 32 slides upwards, the welding gun 71 is restored to an initial state under the action of the welding gun elastic piece 73, and the welding gun stops working after the roller 74 is separated from the linkage plate 33.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims

1. An efficient resonator manufacturing apparatus, characterized in that: including base (1) and punching press portion (3), punching press portion (3) set up on base (1) for the stitch of sheet material punching press formation syntonizer, base (1) below is provided with branch transport mechanism (4) that are used for moving the stitch that the punching press was accomplished the upset, punching press portion (3) slide from top to bottom and drive and divide transport mechanism (4) to move.

2. A high efficiency resonator manufacturing apparatus as defined in claim 1, wherein: the base (1) comprises a guide rod (11) and a die cavity plate (12), the stamping part (3) comprises a stamping power part (31) and a stamping sliding plate (32), the stamping sliding plate (32) is arranged on the guide rod (11) in a sliding mode, the stamping power part (31) is arranged at the top end of the base (1) and connected with the stamping sliding plate (32) to provide vertical sliding power for the stamping sliding plate (32), a punch (34) is arranged at the bottom of the stamping sliding plate (32), and a stamping hole matched with the punch (34) is formed in the die cavity plate (12).

3. A high efficiency resonator manufacturing apparatus as defined in claim 2, wherein: the distribution mechanism (4) comprises a sliding rack device (41), a first connecting rod (42), a second connecting rod (43), a first steering block (44), a pin collecting block (45) and a sliding groove block (46), the sliding groove block (46) is arranged below the cavity plate (12), a first cavity is arranged between the two, the pin collecting block (45) is arranged in the first cavity in a sliding way, the left and the right are respectively provided with one pin collecting block (45), the middle of the pin collecting block is provided with a groove for accommodating pins, and one end of the first connecting rod (42) and one end of the second connecting rod (43) are respectively arranged on the overturning pieces (451) of the left and right stitch collecting blocks (45), and the other end is arranged on the sliding rack device (41), the sliding rack device (41) slides up and down to drive the pin collecting block (45) to slide left and right.

4. A high efficiency resonator manufacturing apparatus as defined in claim 3, wherein: the sliding groove block (46) is provided with a second sliding groove (462) for turning the pin collecting block (45) and a first sliding groove (461) for limiting the first steering block (44), the sliding rack device (41) comprises a lifting rod (411), a first rack (412), a second elastic piece (416) and a first guide rod (413), the sliding rack device (41) is arranged on a bottom plate of the sliding groove block (46) in a sliding mode through the first guide rod (413), the first guide rod (413) is provided with the second elastic piece (416), the lifting rod (411) is arranged on the die cavity plate (12) in a sliding mode, the top end of the lifting rod is matched with the stamping sliding plate (32), a first gear (441) is arranged on the first steering block (44), the sliding rack device (41) comprises a first rack (412), the first rack (412) is matched with the first gear (441), and the first rack (412) slides up and down to drive the first gear (441) to rotate, the first steering block (44) is driven to rotate.

5. A device for manufacturing a high efficiency resonator as claimed in claim 4, wherein: the first connecting rod (42) and the second connecting rod (43) can be produced when being subjected to tensile force, and return to the initial state when the tensile force disappears.