CN212470490U - Automatic kludge of high frequency oscillator - Google Patents

Abstract

The utility model relates to the technical field of automatic assembly, in particular to an automatic assembling machine for high-frequency vibrators, which comprises a turntable and a turntable driving mechanism for driving the turntable to rotate, wherein a plurality of jigs for placing the high-frequency vibrators are arranged on the circumferential array of the turntable; the automatic assembling machine for the high-frequency oscillator further comprises a first antenna buckle assembling mechanism, a first antenna assembling mechanism, a second antenna buckle assembling mechanism, a second antenna assembling mechanism and a discharging mechanism which are arranged around the rotary table; the first antenna buckle mounting mechanism and the second antenna buckle mounting mechanism are respectively used for mounting an external antenna buckle on a high-frequency oscillator in the jig; the first antenna installing mechanism and the second antenna installing mechanism are respectively used for installing an external antenna on a high-frequency oscillator in the jig; the blanking mechanism is used for blanking the high-frequency oscillator provided with the antenna and the antenna buckle to the outside. The utility model discloses an automatic kludge of high frequency oscillator has solved the slower problem of high frequency oscillator packaging efficiency.

Description

Automatic kludge of high frequency oscillator

Technical Field

The utility model relates to an automatic equipment technical field, concretely relates to automatic kludge of high frequency oscillator.

Background

The high-frequency oscillator (also called antenna oscillator) is a component on the communication antenna, and has the functions of guiding and amplifying electromagnetic waves, so that the electromagnetic signals received by the antenna are stronger. The antenna element is made of metal with good conductivity, and the element has a simple rod shape and a complex structure. The high-frequency oscillator with a complex structure can be used after being assembled; however, most of the existing high-frequency oscillators are assembled manually, and the efficiency is low.

Disclosure of Invention

In order to overcome the shortcoming and the deficiency that exist among the prior art, the utility model aims to provide an automatic kludge of high frequency oscillator has solved the slower problem of high frequency oscillator packaging efficiency.

The utility model discloses a realize through following technical scheme:

the automatic assembling machine for the high-frequency vibrators comprises a rotary table and a rotary table driving mechanism for driving the rotary table to rotate, wherein a plurality of jigs for placing the high-frequency vibrators are arranged on the circumferential array of the rotary table; the automatic assembling machine for the high-frequency oscillator further comprises a first antenna buckle assembling mechanism, a first antenna assembling mechanism, a second antenna buckle assembling mechanism, a second antenna assembling mechanism and a discharging mechanism which are arranged around the rotary table; the first antenna buckle mounting mechanism and the second antenna buckle mounting mechanism are respectively used for mounting an external antenna buckle on a high-frequency oscillator in the jig; the first antenna installing mechanism and the second antenna installing mechanism are respectively used for installing an external antenna on a high-frequency oscillator in the jig; the blanking mechanism is used for blanking the high-frequency oscillator provided with the antenna and the antenna buckle to the outside.

The first antenna buckle mounting mechanism comprises an antenna buckle disc, an antenna buckle mounting platform and an antenna buckle clamping and taking mechanism, wherein the antenna buckle mounting platform is provided with an antenna buckle positioning groove for placing an antenna buckle, and the discharge end of the antenna buckle disc is communicated with the antenna buckle positioning groove; the antenna buckle clamping mechanism (33) is arranged above the antenna buckle mounting carrier and used for clamping and mounting the antenna buckle positioned in the antenna buckle mounting carrier to the high-frequency oscillator positioned in the jig.

The antenna buckle clamping mechanism comprises an antenna buckle finger cylinder, an antenna buckle rotation driving mechanism, an antenna buckle lifting mechanism and an antenna buckle transverse moving mechanism, wherein the antenna buckle finger cylinder is used for clamping an antenna buckle from an antenna buckle positioning groove, the antenna buckle rotation driving mechanism is used for driving the antenna buckle finger cylinder to rotate, the antenna buckle lifting mechanism is used for driving the antenna buckle rotation driving mechanism to lift, and the antenna buckle transverse moving mechanism is used for driving the antenna buckle lifting mechanism to transversely move.

The antenna buckle rotation driving mechanism comprises a servo motor and a first transmission rod, the first transmission rod and an output shaft of the servo motor rotate coaxially, and one end, far away from the servo motor, of the first transmission rod is connected with the bottom end of the antenna buckle finger cylinder; first transfer line cover is equipped with the count dish, one side of count dish is equipped with the count sensor that is used for counting the number of turns of count dish pivoted.

The first antenna loading mechanism comprises an antenna tray, an antenna loading platform and an antenna clamping mechanism, the antenna loading platform is provided with an antenna positioning groove for placing an antenna, and the discharge end of the antenna tray is communicated with the antenna positioning groove; the antenna clamping and taking mechanism (33) is arranged above the antenna loading platform and used for clamping and mounting the antenna in the antenna loading platform to the high-frequency oscillator in the jig.

The antenna clamping mechanism comprises an antenna finger cylinder for clamping an antenna from an antenna positioning groove, an antenna rotation driving mechanism for driving the antenna finger cylinder to rotate, an antenna lifting mechanism for driving the antenna rotation driving mechanism to lift and an antenna transverse moving mechanism for driving the antenna lifting mechanism to transversely move.

The antenna rotation driving mechanism comprises a linear cylinder, a rack, a gear and a second transmission rod, one end of the rack is connected with a piston rod of the linear cylinder, and the gear is meshed with the rack; the gear sleeve is arranged on the second transmission rod, and one end, far away from the gear, of the second transmission rod is connected with the bottom end of the antenna finger cylinder.

The structure of the first antenna fastening mechanism is the same as that of the second antenna fastening mechanism, and the structure of the first antenna fastening mechanism is the same as that of the second antenna fastening mechanism; the first antenna installing mechanism is arranged between the first antenna installing buckle mechanism and the second antenna installing buckle mechanism, and the second antenna installing mechanism is arranged between the second antenna installing buckle mechanism and the blanking mechanism.

The blanking mechanism comprises a blanking finger cylinder, a blanking lifting mechanism used for driving the blanking finger cylinder to lift and a blanking transverse moving mechanism used for driving the blanking lifting mechanism to transversely move.

The discharging mechanism is arranged on the lower portion of the feeding mechanism, a slide is arranged below the discharging mechanism, and the tail end of the slide is communicated with a storage box.

The utility model has the advantages that:

the problem of the high frequency oscillator packaging efficiency is slower is solved: the utility model discloses an automatic kludge of high frequency oscillator, be provided with the carousel, carousel actuating mechanism and a plurality of tool, the rotation through the carousel drives the tool and removes in proper order and detains the mechanism to first dress antenna, first dress antenna mechanism, the second dress antenna detains mechanism and second dress antenna mechanism department and assembles, treat to carry out the unloading by unloading mechanism to the high frequency oscillator after the equipment again to make full-automatic equipment and the unloading of carrying on of high frequency oscillator, the packaging efficiency of high frequency oscillator has been increased.

Drawings

The present invention is further explained by using the drawings, but the embodiments in the drawings do not constitute any limitation to the present invention, and for those skilled in the art, other drawings can be obtained according to the following drawings without any inventive work.

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic structural view of the first antenna fastening mechanism of the present invention.

Fig. 3 is a schematic structural diagram of a first antenna mounting mechanism according to the present invention.

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

Reference numerals

A rotating disk-1, a fixture-2,

a first antenna buckle mounting mechanism-3, an antenna buckle tray-31, an antenna buckle mounting carrier-32,

an antenna buckle clamping mechanism-33, an antenna buckle finger cylinder-331, an antenna buckle rotation driving mechanism-332, an antenna buckle lifting mechanism-333, an antenna buckle transverse moving mechanism-334, a servo motor-335, a first transmission rod-336, a counting disc-337, a counting sensor-338, an antenna buckle positioning groove-34,

a first antenna loading mechanism-4, an antenna tray-41, an antenna loading platform-42,

an antenna clamping mechanism-43, an antenna finger cylinder-431, an antenna rotation driving mechanism-432, an antenna lifting mechanism-433, an antenna transverse moving mechanism-434, a linear cylinder-435, a rack-436, a gear-437, a second transmission rod-438, an antenna positioning groove-44,

a second antenna buckle mounting mechanism-5, a second antenna mounting mechanism-6,

a blanking mechanism-7, a blanking finger cylinder-71, a blanking lifting mechanism-72, a blanking traversing mechanism-73, a slide-74 and a storage box-75.

Detailed Description

The following description of the embodiments of the present invention is provided for illustrative purposes, and other advantages and effects of the present invention will be readily apparent to those skilled in the art from the disclosure herein. The present invention can also be implemented or applied through other different specific embodiments, and various details in the present specification can be modified or changed based on different viewpoints and applications without departing from the spirit of the present invention.

It should be noted that the structures shown in the drawings are only used for matching with the contents disclosed in the specification, so as to be understood and read by those skilled in the art, and are not used for limiting the practical limitations of the present invention, so that the modifications or adjustments of any structure do not have the essential meaning in the art, and the technical contents disclosed in the present invention should still fall within the scope that the functions and the achievable objects of the present invention can be achieved without affecting the present invention.

As shown in fig. 1 to 4, an automatic assembling machine for high-frequency oscillators includes a turntable 1 and a turntable driving mechanism (not shown in the figure) for driving the turntable 1 to rotate, wherein a plurality of jigs 2 for placing high-frequency oscillators are arranged on the top circumference array of the turntable 1; the automatic assembling machine for the high-frequency oscillator further comprises a first antenna buckle assembling mechanism 3, a first antenna buckle assembling mechanism 4, a second antenna buckle assembling mechanism 5, a second antenna buckle assembling mechanism 6 and a blanking mechanism 7 which are arranged around the rotary table 1; the first antenna buckle installing mechanism 3 and the second antenna buckle installing mechanism 5 are respectively used for installing an external antenna buckle on a high-frequency oscillator in the jig 2; the first antenna installing mechanism 4 and the second antenna installing mechanism 6 are respectively used for installing external antennas on the high-frequency oscillator in the jig 2; and the blanking mechanism 7 is used for blanking the high-frequency oscillator provided with the antenna and the antenna buckle to the outside.

In this embodiment, the structure of the first antenna fastening mechanism 3 is the same as that of the second antenna fastening mechanism 5, and the structure of the first antenna fastening mechanism 4 is the same as that of the second antenna fastening mechanism 6; first dress antenna mechanism 4 is located between first dress antenna knot mechanism 3 and second dress antenna knot mechanism 5, second dress antenna mechanism 6 is located between second dress antenna knot mechanism 5 and unloading mechanism 7. The turntable 1 is driven by the turntable driving mechanism to rotate according to a certain frequency and amplitude, and the frequency and the amplitude depend on the time for assembling each mechanism; firstly, an external manipulator high-frequency reduction vibrator is put into a corresponding position of the jig 2, and the turntable 1 rotates to a next station, and the antenna buckle is installed in the first antenna buckle installing mechanism 3; the rotation direction of the turntable 1 is sequentially from a first antenna-mounting buckle mechanism 3, a first antenna-mounting mechanism 4, a second antenna-mounting buckle mechanism 5, a second antenna-mounting buckle mechanism 6 to a blanking mechanism 7, and finally blanking is carried out in the blanking mechanism 7 after the high-frequency oscillator is assembled.

Specifically, the first antenna buckle mounting mechanism 3 includes an antenna buckle tray 31, an antenna buckle mounting carrier 32 and an antenna buckle clamping mechanism 33, the antenna buckle mounting carrier 32 is provided with an antenna buckle positioning groove 34 for placing an antenna buckle, and a discharge end of the antenna buckle tray 31 is communicated with the antenna buckle positioning groove 34; the antenna buckle clamping mechanism 33 is arranged above the antenna buckle mounting stage 32, and the antenna buckle clamping mechanism 33 is used for clamping and mounting the antenna buckle positioned in the antenna buckle mounting stage 32 onto the high-frequency oscillator positioned in the jig 2. The antenna buckle clamping mechanism 33 includes an antenna buckle finger cylinder 331 for clamping the antenna buckle from the antenna buckle positioning slot 34, an antenna buckle rotation driving mechanism 332 for driving the antenna buckle finger cylinder 331 to rotate, an antenna buckle lifting mechanism 333 for driving the antenna buckle rotation driving mechanism 332 to lift, and an antenna buckle traversing mechanism 334 for driving the antenna buckle lifting mechanism 333 to traverse. In this embodiment, the antenna fastening disc 31 is a vibrating disc, the antenna fastening lifting mechanism 333 is a driving mechanism composed of a cylinder, a slider and a slide rail, and the antenna fastening traversing mechanism 334 is a driving mechanism composed of a motor, a slider, a belt and a belt pulley.

In practical use, the antenna buckle tray 31 is filled with the antenna buckles to be assembled and continuously conveys the antenna buckles to the antenna buckle assembling platform 32; simultaneously, the antenna buckle finger cylinder 331 is driven by the linkage of the antenna buckle traversing mechanism 334 and the antenna buckle lifting mechanism 333 to reach the corresponding position of the antenna buckle mounting platform 32, the antenna buckle is rotated to the correct angle by the antenna buckle rotating mechanism in the process, then the antenna buckle is clamped by the antenna buckle finger cylinder 331 and the antenna buckle is clamped by the antenna buckle traversing mechanism 334 and the linkage of the antenna buckle lifting mechanism 333 to drive the antenna buckle to move to the corresponding position of the jig 2, and then the antenna buckle finger cylinder 331 is released to enable the antenna buckle to fall into the jig 2 and be mounted on a high-frequency oscillator, so that the assembly of the antenna buckle is completed; the antenna buckle finger cylinder 331 is driven by the linkage of the antenna buckle traversing mechanism 334 and the antenna buckle lifting mechanism 333 to reset, and then the next round of clamping of the antenna buckle is started.

Specifically, the antenna buckle rotation driving mechanism 332 includes a servo motor 335 and a first transmission rod 336, the first transmission rod 336 rotates coaxially with the output shaft of the servo motor 335, and the antenna buckle finger cylinder 331 is installed on the first transmission rod 336 and rotates synchronously with the first transmission rod 336; the first transmission rod 336 is sleeved with a counting disc 337, and one side of the counting disc 337 is provided with a counting sensor 338 for counting the number of turns of the counting disc 337. When the servo motor 335 drives the antenna fastening finger cylinder 331 to rotate through the first transmission rod 336, the counting disc 337 also rotates along with the first transmission rod 336; the counting sensor 338 is arranged, so that the rotation times of the antenna buckle finger cylinder 331 are conveniently monitored; preferably, the counter sensor 338 is an infrared sensor.

It should be noted that, since the structure of the second antenna fastening mechanism 5 is the same as that of the first antenna fastening mechanism 3, the principle of how the second antenna fastening mechanism 5 fastens the antenna to the high-frequency oscillator in the fixture 2 is the same as that of the first antenna fastening mechanism 3, and is not described herein again.

Specifically, the first antenna loading mechanism 4 includes an antenna tray 41, an antenna loading platform 42 and an antenna clamping mechanism 43, the antenna loading platform 42 is provided with an antenna positioning slot 44 for placing an antenna, and a discharge end of the antenna tray 41 is communicated with the antenna positioning slot 44; the antenna clamping mechanism 43 is disposed above the antenna loading table 42, and the antenna clamping mechanism 43 is configured to clamp and mount the antenna located in the antenna loading table 42 to the high-frequency oscillator located in the fixture 2. The antenna gripping mechanism 43 includes an antenna finger cylinder 431 for gripping the antenna from the antenna positioning groove 44, an antenna rotation driving mechanism 432 for driving the antenna finger cylinder 431 to rotate, an antenna elevating mechanism 433 for driving the antenna rotation driving mechanism 432 to ascend and descend, and an antenna traverse mechanism 434 for driving the antenna elevating mechanism 433 to traverse. In this embodiment, the antenna tray 41 is a vibrating tray, the antenna lifting mechanism 433 is a driving mechanism composed of a cylinder, a slider and a slide rail, and the antenna traversing mechanism 434 is a driving mechanism composed of a motor, a slider, a belt and a belt pulley.

In actual use, the antenna tray 41 is filled with the antennas to be assembled and continuously conveys the antennas to the antenna loading platform 42; simultaneously, the antenna finger cylinder 431 is driven to reach the corresponding position of the antenna loading platform 42 through the linkage of the antenna transverse moving mechanism 434 and the antenna lifting mechanism 433 respectively, the antenna is rotated to a correct angle through the antenna rotating mechanism in the process, then the antenna is clamped by the antenna finger cylinder 431 and is driven to move to the corresponding position of the jig 2 through the linkage of the antenna transverse moving mechanism 434 and the antenna lifting mechanism 433, and the antenna finger cylinder 431 is loosened to complete the assembly of the antenna; and the antenna finger cylinder 431 is driven to reset by the linkage of the antenna transverse moving mechanism 434 and the antenna lifting mechanism 433, so that the next round of antenna clamping is started.

Specifically, the antenna rotation driving mechanism 432 comprises a linear cylinder 435, a rack 436, a gear 437 and a second transmission rod 438, the linear cylinder 435 is installed on the antenna transverse moving mechanism 434, one end of the rack 436 is connected with a piston rod of the linear cylinder 435, and the gear 437 is meshed with the rack 436; the gear 437 is sleeved on the second transmission rod 438, and the antenna finger cylinder 431 is installed on the second transmission rod 438 and rotates synchronously with the second transmission rod 438. The rack 436 can be controlled to drive the gear 437 to rotate by extending or retracting the piston of the linear cylinder 435, so as to drive the antenna finger cylinder 431 to rotate.

It should be noted that, since the structure of the second antenna mounting mechanism 6 is the same as that of the first antenna mounting mechanism 4, the principle of how the second antenna mounting mechanism 6 mounts the antenna on the high-frequency oscillator located in the jig 2 is the same as that of the first antenna mounting mechanism 4, and details thereof are not repeated.

Specifically, the blanking mechanism 7 includes a blanking finger cylinder 71 for clamping the mounted antenna, a blanking lifting mechanism 72 for driving the blanking finger cylinder 71 to lift, and a blanking transverse moving mechanism 73 for driving the blanking lifting mechanism 72 to transversely move. A slide 74 is arranged below the blanking mechanism 7, and the tail end of the slide 74 is communicated with a storage box 75. In this embodiment, the blanking lifting mechanism 72 is a driving mechanism composed of a rodless cylinder and a sliding block, and the blanking traversing mechanism 73 is a driving mechanism composed of a rodless cylinder and a sliding block, and for the driving principle of the driving mechanism, reference may be made to the prior art specifically, and details are not described here.

When the high-frequency vibrator is actually used, after the high-frequency vibrator is assembled in sequence, the turntable 1 drives the jig 2 provided with the high-frequency vibrator to rotate to the position of the blanking mechanism 7, the blanking finger cylinders 71 are driven to reach the corresponding positions of the jig 2 through linkage of the blanking transverse moving mechanism 73 and the blanking lifting mechanism 72, the blanking finger cylinders 71 clamp the high-frequency vibrator from the jig 2 and drive the blanking finger cylinders 71 to clamp the high-frequency vibrator to move above a landslide through linkage of the blanking transverse moving mechanism 73 and the blanking lifting mechanism 72, the blanking finger cylinders 71 are loosened, and the high-frequency vibrator is transferred into the storage box 75 along the landslide; the blanking transverse moving mechanism 73 and the blanking lifting mechanism 72 are linked to drive the blanking finger cylinder 71 to reset so as to start the next blanking.

It should be finally noted that the above embodiments are only intended to illustrate the technical solutions of the present invention, and not to limit the scope of the present invention, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solutions of the present invention can be modified or replaced with equivalents without departing from the spirit and scope of the technical solutions of the present invention.

Claims (10)

1. The automatic assembling machine for the high-frequency oscillator is characterized in that: the high-frequency vibrator rotating table comprises a rotating table (1) and a rotating table driving mechanism for driving the rotating table (1) to rotate, wherein a plurality of jigs (2) for placing high-frequency vibrators are arranged on the circumferential array of the rotating table (1);

the automatic assembling machine for the high-frequency oscillator further comprises a first antenna installing buckle mechanism (3), a first antenna installing mechanism (4), a second antenna installing buckle mechanism (5), a second antenna installing mechanism (6) and a blanking mechanism (7) which are arranged around the rotary table (1); the first antenna buckle installing mechanism (3) and the second antenna buckle installing mechanism (5) are respectively used for installing an external antenna buckle on a high-frequency oscillator in the jig (2); the first antenna installing mechanism (4) and the second antenna installing mechanism (6) are respectively used for installing external antennas on the high-frequency oscillator in the jig (2); and the blanking mechanism (7) is used for blanking the high-frequency oscillator provided with the antenna and the antenna buckle to the outside.

2. The automatic assembling machine for high-frequency vibrators according to claim 1 is characterized in that: the first antenna buckle mounting mechanism (3) comprises an antenna buckle disc (31), an antenna buckle mounting carrier (32) and an antenna buckle clamping mechanism (33), the antenna buckle mounting carrier (32) is provided with an antenna buckle positioning groove (34) for placing an antenna buckle, and the discharge end of the antenna buckle disc (31) is communicated with the antenna buckle positioning groove (34); the antenna buckling and clamping mechanism (33) is arranged above the antenna buckling and clamping carrier (32), and the antenna buckling and clamping mechanism (33) is used for clamping and mounting an antenna buckle positioned in the antenna buckling and clamping carrier (32) to a high-frequency oscillator positioned in the jig (2).

3. The automatic assembling machine for high-frequency vibrators according to claim 2 is characterized in that: the antenna buckle clamping mechanism (33) comprises an antenna buckle finger cylinder (331) used for clamping an antenna buckle from an antenna buckle positioning groove (34), an antenna buckle rotation driving mechanism (332) used for driving the antenna buckle finger cylinder (331) to rotate, an antenna buckle lifting mechanism (333) used for driving the antenna buckle rotation driving mechanism (332) to lift and an antenna buckle transverse moving mechanism (334) used for driving the antenna buckle lifting mechanism (333) to transversely move.

4. The automatic assembling machine for high-frequency vibrators according to claim 3 is characterized in that: the antenna buckle rotation driving mechanism (332) comprises a servo motor (335) and a first transmission rod (336), and the antenna buckle finger cylinder (331) is arranged on the first transmission rod (336) and rotates synchronously with the first transmission rod (336); one end of the first transmission rod (336), which is far away from the servo motor (335), is connected with the bottom end of the antenna buckle finger cylinder (331); the counting device is characterized in that the first transmission rod (336) is sleeved with a counting disc (337), and a counting sensor (338) used for counting the number of turns of the rotating counting disc (337) is arranged on one side of the counting disc (337).

5. The automatic assembling machine for high-frequency vibrators according to claim 1 is characterized in that: the first antenna loading mechanism (4) comprises an antenna tray (41), an antenna loading platform (42) and an antenna clamping mechanism (43), the antenna loading platform (42) is provided with an antenna positioning groove (44) for placing an antenna, and the discharge end of the antenna tray (41) is communicated with the antenna positioning groove (44); the antenna clamping mechanism (43) is arranged above the antenna loading platform (42), and the antenna clamping mechanism (43) is used for clamping and mounting the antenna positioned in the antenna loading platform (42) to the high-frequency oscillator positioned in the jig (2).

6. The automatic assembling machine for high-frequency vibrators according to claim 5 is characterized in that: the antenna clamping mechanism (43) comprises an antenna finger cylinder (431) for clamping an antenna from the antenna positioning groove (44), an antenna rotation driving mechanism (432) for driving the antenna finger cylinder (431) to rotate, an antenna lifting mechanism (433) for driving the antenna rotation driving mechanism (432) to lift and a antenna transverse moving mechanism (434) for driving the antenna lifting mechanism (433) to transversely move.

7. The automatic assembling machine for high-frequency vibrators according to claim 6 is characterized in that: the antenna rotation driving mechanism (432) comprises a linear air cylinder (435), a rack (436), a gear (437) and a second transmission rod (438), the linear air cylinder (435) is arranged on the antenna transverse moving mechanism (434), one end of the rack (436) is connected with a piston rod of the linear air cylinder (435), and the gear (437) is meshed with the rack (436); the gear (437) is sleeved on the second transmission rod (438), the antenna finger cylinder (431) is arranged on the second transmission rod (438) and rotates synchronously with the second transmission rod (438), and one end, far away from the gear (437), of the second transmission rod (438) is connected with the bottom end of the antenna finger cylinder (431).

8. The automatic assembling machine for high-frequency vibrators according to claim 1 is characterized in that: the structure of the first antenna buckle installing mechanism (3) is the same as that of the second antenna buckle installing mechanism (5), and the structure of the first antenna buckle installing mechanism (4) is the same as that of the second antenna buckle installing mechanism (6); the first antenna installing mechanism (4) is arranged between the first antenna installing buckle mechanism (3) and the second antenna installing buckle mechanism (5), and the second antenna installing mechanism (6) is arranged between the second antenna installing buckle mechanism (5) and the blanking mechanism (7).

9. The automatic assembling machine for high-frequency vibrators according to claim 1 is characterized in that: the blanking mechanism (7) comprises a blanking finger cylinder (71), a blanking lifting mechanism (72) used for driving the blanking finger cylinder (71) to lift and a blanking transverse moving mechanism (73) used for driving the blanking lifting mechanism (72) to transversely move.

10. The automatic assembling machine for high-frequency vibrators according to claim 9 is characterized in that: a slide (74) is arranged below the blanking mechanism (7), and the tail end of the slide (74) is communicated with a storage box (75).

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