CN220753725U - Antenna production equipment - Google Patents

Abstract

The utility model relates to antenna production and assembly equipment which is characterized by comprising a positioning seat body, a left transverse pushing mechanism, a right transverse pushing mechanism and a positioning block body, wherein the left transverse pushing mechanism and the right transverse pushing mechanism are arranged on the positioning seat body side by side left and right, the movable end of the left transverse pushing mechanism and the movable end of the right transverse pushing mechanism are oppositely arranged, the positioning block body is arranged between the left transverse pushing mechanism and the right transverse pushing mechanism, and a positioning notch which transversely penetrates through is formed in the positioning block body. The utility model can be favorable for rapidly and accurately positioning the antenna bracket, and can rapidly and stably complete the assembly of the antenna bracket, thereby not only reducing the labor intensity of workers, but also improving the assembly efficiency and keeping the assembly quality in a very high state for a long time.

Description

Antenna production equipment

Technical Field

The utility model relates to the field of antenna production equipment, in particular to antenna production and assembly equipment.

Background

At present, the applicant has developed a novel unmanned aerial vehicle WiFi antenna, and the unmanned aerial vehicle WiFi antenna has additionally filed a patent application. As shown in fig. 1 and fig. 2, this kind of unmanned aerial vehicle WiFi antenna includes antenna boom 100, antenna main body 200, antenna boom 100 includes locating sleeve 101, half gentle coaxial line 102, antenna adapter 103, two gum covers 104, and two gum covers 104 are put at half gentle coaxial line 102's both ends respectively, half gentle coaxial line 102's both ends cartridge respectively is on locating sleeve 101, antenna adapter 103 to make two gum covers 104 suit respectively in locating sleeve 101 and half gentle coaxial line 102's junction, antenna adapter 103 and half gentle coaxial line 102's junction, antenna main body 200 sets up on antenna adapter 103.

In order to make the assembly structure of the antenna bracket 100 have high stability and reliability, the positioning sleeve 101 and the semi-flexible coaxial line 102, the antenna adapter 103 and the semi-flexible coaxial line 102, the positioning sleeve 101 and the corresponding rubber sleeve 104, the antenna adapter 103 and the corresponding rubber sleeve 104, and the rubber sleeve 104 and the semi-flexible coaxial line 102 are all in relatively tight nested connection. Therefore, the antenna bracket 100 is very time-consuming and labor-consuming to assemble manually, and the assembly worker is very easy to have the condition of too fast fatigue in the assembly process, which not only can lead to very low assembly efficiency of the antenna bracket 100, but also can lead to difficulty in stabilizing the assembly quality of the antenna bracket 100 in a good state due to fatigue of the worker.

While antenna production and assembly equipment exists today, existing antenna production and assembly equipment is designed for antenna stands of a specific construction, i.e. one antenna production and assembly equipment is only suitable for assembling one antenna stand. Since the antenna stand 100 is not present, there is no antenna production and assembly equipment suitable for assembling the antenna stand 100, which brings a lot of trouble to the production of the WiFi antenna of the unmanned aerial vehicle.

Therefore, there is an urgent need for an antenna production assembly apparatus for assembling the above-mentioned unmanned aerial vehicle WiFi antenna.

Disclosure of Invention

The utility model aims to solve the problems and the shortcomings, and provides an antenna production and assembly device which can be used for rapidly and accurately positioning an antenna bracket and rapidly and stably assembling the antenna bracket, so that the labor intensity of workers can be reduced, the assembly efficiency can be improved, the assembly quality can be kept in a very high state for a long time, and the antenna production and assembly device has the advantages of good positioning effect, high assembly quality, high assembly efficiency, wide application range, strong applicability and the like.

The technical scheme of the utility model is realized as follows:

the antenna production assembly equipment is characterized by comprising a positioning seat body, a left transverse pushing mechanism, a right transverse pushing mechanism and a positioning block body, wherein the left transverse pushing mechanism and the right transverse pushing mechanism are arranged on the positioning seat body side by side left and right, the movable end of the left transverse pushing mechanism and the movable end of the right transverse pushing mechanism are oppositely arranged, the positioning block body is arranged between the left transverse pushing mechanism and the right transverse pushing mechanism, and a positioning notch which transversely penetrates through is formed in the positioning block body.

Preferably, the positioning seat body comprises a base and a wear-resistant table, the wear-resistant table is arranged in the middle of the base, the left transverse pushing mechanism and the right transverse pushing mechanism are respectively arranged at the left end and the right end of the base, the movable end of the left transverse pushing mechanism and the movable end of the right transverse pushing mechanism are in sliding lap joint with the wear-resistant table, and the positioning block body is arranged on the wear-resistant table.

Preferably, a hiding box is arranged on the bottom surface of the base.

Preferably, the left transverse pushing mechanism comprises a left cylinder and a left pushing block, wherein the left cylinder is transversely arranged at the left end of the positioning seat body, the telescopic end of the left cylinder faces to the right, and the left pushing block is arranged at the telescopic end of the left cylinder.

Preferably, a convex column part is arranged on the right surface of the left pushing block.

Preferably, the right horizontal pushing mechanism comprises a right cylinder and a right pushing block, wherein the right cylinder is transversely arranged at the right end of the positioning seat body, the telescopic end of the right cylinder faces to the left, and the right pushing block is arranged at the telescopic end of the right cylinder.

Preferably, the positioning block comprises at least one positioning block, and the positioning notch transversely penetrates through the top of each positioning block; when the positioning blocks are only one, the positioning blocks can be detachably lapped on the positioning seat body; when more than two positioning blocks are arranged, the positioning blocks are transversely arranged side by side, positioning gaps on the positioning blocks are in butt joint communication, and the positioning blocks are detachably lapped on the positioning seat body or one of the positioning blocks is fixedly arranged on the positioning seat body, and the other positioning blocks can be detachably lapped on the positioning seat body.

Preferably, at least two positioning blocks are provided, and the positioning seat body is provided with an anti-pinch cover, so that the anti-pinch cover covers each positioning block.

Preferably, the anti-pinch cover is rotatably arranged on the positioning seat body, and can be separated from the positioning block in a rotating way.

Preferably, the antenna production and assembly equipment further comprises a pedal controller, and the left transverse pushing mechanism and the right transverse pushing mechanism are in control connection with the pedal controller.

The utility model has the beneficial effects that: on the antenna production assembly equipment, through the arrangement of the positioning block body and the positioning notch arranged on the positioning block body, the antenna bracket component can be positioned quickly and accurately. The left transverse pushing mechanism and the right transverse pushing mechanism are adopted, so that a bidirectional pushing effect can be achieved, the antenna production and assembly equipment has a quite large pushing range, the antenna production and assembly equipment can push antenna brackets with more lengths, and the antenna production and assembly equipment has a quite large application range. The antenna bracket can be assembled quickly and stably through the left transverse pushing mechanism and the right transverse pushing mechanism, so that the labor intensity of workers can be reduced conveniently, the assembly efficiency can be improved, the assembly quality can be kept in a very high state for a long time, and the antenna production and assembly equipment has very strong applicability. The antenna production and assembly equipment is very suitable for producing the antenna bracket, and the trouble of producing the WiFi antenna of the unmanned aerial vehicle can be greatly reduced. The antenna production and assembly equipment has the advantages of good positioning effect, high assembly quality, high assembly efficiency, wide application range, strong applicability and the like.

Drawings

Fig. 1 is a schematic perspective view of a WiFi antenna of an unmanned aerial vehicle designed by the applicant.

Fig. 2 is a schematic diagram of a split structure of a WiFi antenna of an unmanned aerial vehicle designed by the applicant.

Fig. 3 is a schematic perspective view of an antenna production and assembly apparatus according to the present utility model.

Fig. 4 is a schematic diagram of a structure of an antenna production and assembly device in a front view direction.

Fig. 5 is a schematic diagram of a split structure of an antenna production and assembly device according to the present utility model.

FIG. 6 is a schematic cross-sectional view of the containing box of the present utility model.

FIG. 7 is a schematic diagram of an assembled structure of a positioning block and a wear table according to the present utility model.

Fig. 8 is a schematic perspective view of a left lateral pushing mechanism in the present utility model.

Fig. 9 is a schematic perspective view of a right lateral pushing mechanism according to the present utility model.

Fig. 10 is a schematic diagram of a structure for accommodating a semi-finished antenna support according to the present utility model.

Fig. 11 is a schematic structural view of a pushing semi-finished antenna support according to the present utility model.

Fig. 12 is a schematic diagram showing a state change from a semi-finished antenna support to a finished product according to the present utility model.

Description of the embodiments

As shown in fig. 3 to 5, the antenna production and assembly device of the present utility model includes a positioning seat 1, a left lateral pushing mechanism 2, a right lateral pushing mechanism 3, and a positioning block 4, wherein the left lateral pushing mechanism 2 and the right lateral pushing mechanism 3 are arranged on the positioning seat 1 side by side left and right, and a movable end of the left lateral pushing mechanism 2 and a movable end of the right lateral pushing mechanism 3 are arranged opposite to each other, the positioning block 4 is arranged between the left lateral pushing mechanism 2 and the right lateral pushing mechanism 3, and a positioning notch 10 penetrating transversely is formed in the positioning block 4.

In the antenna production and assembly equipment, the positioning block 4 is provided, and the positioning block 4 is provided with the positioning notch 10, so that the antenna bracket component can be positioned quickly and accurately. The left transverse pushing mechanism 2 and the right transverse pushing mechanism 3 are adopted, so that a bidirectional pushing effect can be achieved, the antenna production and assembly equipment has a quite large pushing range, the antenna production and assembly equipment can push antenna brackets with various lengths, and the antenna production and assembly equipment has a quite large application range.

And the left horizontal pushing mechanism 2 and the right horizontal pushing mechanism 3 can play a role in quick and stable pushing, so that the antenna bracket can be quickly and stably assembled, the labor intensity of workers can be conveniently reduced, the assembly efficiency can be improved, the assembly quality can be kept in a very high state for a long time, and the antenna production and assembly equipment has very strong applicability. The antenna production and assembly equipment is very suitable for producing the antenna bracket, and the trouble of producing the WiFi antenna of the unmanned aerial vehicle can be greatly reduced.

The antenna production and assembly equipment has the advantages of good positioning effect, high assembly quality, high assembly efficiency, wide application range, strong applicability and the like.

In the antenna production and assembly equipment, the movable end of the left transverse pushing mechanism 2 and the movable end of the right transverse pushing mechanism 3 can do reciprocating motion far away from each other and close to each other, so that the pushing effect can be well completed.

As shown in fig. 5, the positioning seat body 1 includes a base 11 and a wear-resistant table 12, the wear-resistant table 12 is disposed in the middle of the base 11, the left lateral pushing mechanism 2 and the right lateral pushing mechanism 3 are respectively disposed at left and right ends of the base 11, and the movable end of the left lateral pushing mechanism 2 and the movable end of the right lateral pushing mechanism 3 are slidably lapped on the wear-resistant table 12, and the positioning block 4 is disposed on the wear-resistant table 12. The abrasion-resistant table 12 can play a role in supporting and limiting the movable ends of the left transverse pushing mechanism 2 and the right transverse pushing mechanism 3, so that the stability and the accuracy of pushing are improved. The wear-resistant table 12 can also reduce the wear rate, thereby prolonging the service life. The abrasion resistant table 12 is adopted only at the movable ends of the left and right lateral thrusting mechanisms 2 and 3, which can facilitate control of manufacturing costs. The movable ends of the left transverse pushing mechanism 2 and the right transverse pushing mechanism 3 are slidably arranged on the wear-resistant table 12 in a lap joint mode, so that the assembly can be facilitated.

The base 11 is made of a PP plastic plate, the wear-resistant table 12 is made of a stainless steel table, and the base 11 and the wear-resistant table 12 can be fixed together through screws or bolts (not shown). This not only enables the positioning socket body 1 to have high structural strength, but also enables the manufacturing cost of the positioning socket body 1 to be well controlled.

As shown in fig. 3 to 5, a storage case 13 is provided on the bottom surface of the base 11. The storage case 13 can conceal the relevant auxiliary components, thereby facilitating the improvement of safety and service life. The Tibetan box 13 is arranged on the bottom surface of the base 11, so that the excessive occupation of the horizontal space of the antenna production and assembly equipment can be avoided, and the application range can be improved.

As shown in fig. 5 and 6, the storage box 13 is a metal box body (e.g., a stainless steel box or an aluminum alloy box) with an open top, the base 11 covers the opening of the storage box 13, the storage box 13 and the base 11 are fixed together by a screw 111 or a bolt, at least one through hole 131 penetrating into the side wall of the storage box 13 is formed in the side wall of the storage box 13, and the through hole 131 can allow an air supply pipe and a wire to pass through and/or penetrate. Thus, better hiding effect can be achieved.

As shown in fig. 4 and 6, a plurality of supporting feet 132 are provided on the bottom surface of the storage box 13. Thus, the antenna can be used in a non-planar environment, and the application range of the antenna production and assembly equipment is improved.

As shown in fig. 4, 5 and 8, the left lateral pushing mechanism 2 includes a left cylinder 21 and a left pushing block 22, the left cylinder 21 is transversely disposed at the left end of the positioning seat 1, and the telescopic end of the left cylinder 21 faces to the right, and the left pushing block 22 is disposed at the telescopic end of the left cylinder 21. The left transverse pushing mechanism 2 is quite simple and reliable, so that the left transverse pushing mechanism can be conveniently manufactured, and a quite good pushing effect can be achieved.

As shown in fig. 5, the left pushing block 22 is slidably connected to the wear-resistant table 12 in a transverse manner, which can perform a stable supporting function on the left pushing block 22 through the wear-resistant table 12.

As shown in fig. 8, 11 and 12, the right surface of the left pushing block 22 is provided with a protruding column portion 23. The convex column part 23 is matched with the sleeve joint port 110 on the end face of the positioning sleeve 101, so that the convex column part 23 can be used for stably and accurately positioning the positioning sleeve 101, and the reliability of the antenna production and assembly equipment can be further improved.

As shown in fig. 4, 5 and 9, the right lateral pushing mechanism 3 includes a right cylinder 31 and a right pushing block 32, the right cylinder 31 is transversely disposed at the right end of the positioning seat 1, and the telescopic end of the right cylinder 31 faces to the left, and the right pushing block 32 is disposed at the telescopic end of the right cylinder 31. The right transverse pushing mechanism 3 is quite simple and reliable, so that the right transverse pushing mechanism can be conveniently manufactured, and a quite good pushing effect can be achieved.

As shown in fig. 5, the right pushing block 32 can be laterally and slidably lapped on the wear-resistant table 12, which can play a role of stably supporting the right pushing block 32 through the wear-resistant table 12.

Because the rubber sleeve 104 has limited structural strength, and the nested connection strength between the positioning sleeve 101 and the semi-flexible coaxial line 102 and between the antenna adapter 103 and the semi-flexible coaxial line 102 is not too strong (the nested connection strength is moderate, and because the rubber sleeve 104 is limited at the connection part, the requirement of actual use can be met. Therefore, under the general use condition, the assembly requirement can be met without adopting great acting force for the left pushing block 22 and the right pushing block 32, so that the left pushing block 22 and the right pushing block 32 do not need guide rail guiding limitation. Of course, a guide rail may be provided to guide the left pushing block 22 and the right pushing block 32.

The left pushing block 22 and the right pushing block 32 are both stainless steel blocks, which can improve the structural strength and durability.

As shown in fig. 8 and 9, the left wall of the left pushing block 22 is provided with at least one left transverse screw 24, and the left end of the left transverse screw 24 faces the right end face of the left cylinder 21, and the left wall of the right pushing block 32 is provided with at least one right transverse screw 33, and the right end of the right transverse screw 33 faces the left end face of the right cylinder 31. The purpose of limiting the backward movement of the left pushing block 22 and the right pushing block 32 can be achieved through the left transverse screw 24 and the right transverse screw 33, so that the left pushing block 22 and the right pushing block 32 are prevented from being separated from the abrasion-resistant table 12 due to backward movement when the short abrasion-resistant table 12 is adopted, and the reliability and the applicability of the antenna production and assembly equipment can be further improved.

As shown in fig. 5 and 7, the positioning block 4 includes at least one positioning block 41, and the positioning notch 10 transversely penetrates through the top of each positioning block 41; when the positioning block 41 is only one, the positioning block 41 can be detachably lapped on the positioning seat body 1; when more than two positioning blocks 41 are arranged, the positioning blocks 41 are transversely arranged side by side, the positioning gaps 10 on the positioning blocks 41 are in butt joint communication, the positioning blocks 41 are detachably lapped on the positioning seat body 1, or one of the positioning blocks 41 is fixedly arranged on the positioning seat body 1, and the other positioning blocks 41 are detachably lapped on the positioning seat body 1. Therefore, the positioning blocks 41 with different transverse widths can be conveniently replaced by a user, so that stable and accurate assembly of antenna brackets with different lengths can be facilitated, and the applicability of the antenna production and assembly equipment can be further improved. When a positioning block 41 is provided, which is fixedly provided, a stable positioning effect can be facilitated, which can ensure that the antenna production and assembly equipment has very high reliability.

As shown in fig. 4 and 5, at least two positioning blocks 41 are provided, and the positioning base 1 is provided with anti-pinch covers 14, so that the anti-pinch covers 14 cover each positioning block 41. The anti-pinch cover 14 can cover the gap between the adjacent positioning blocks 41 to prevent hands from being placed in the gap, so that the anti-pinch function can be achieved, and the use safety is improved.

As shown in fig. 5, the anti-pinch cover 14 is rotatably disposed on the positioning base 1, and enables the anti-pinch cover 14 to be rotatably separated from the positioning block 41. Therefore, the utility model has the advantages of not only playing a very good role in covering, but also facilitating the assembly and disassembly of the positioning block 41, thereby being convenient for use.

As shown in fig. 7, the positioning block 41 is a stainless steel block; when the positioning block 41 needs to be fixedly arranged, the positioning block 41 and the wear-resistant table 12 are made into an integrated structure; when it is desired to detachably overlap the positioning block 41, the positioning block 41 is overlapped on the wear table 12. Thus meeting the requirements of actual production and use.

As shown in fig. 3 and 5, two anti-pinch covers 14 are provided, the two anti-pinch covers 14 are in zigzag structures, the two anti-pinch covers 14 are respectively arranged at the front and rear of the wear-resistant table 12, the lower ends of the two anti-pinch covers 14 can be horizontally and rotatably connected to the base 11, the upper ends of the front and rear anti-pinch covers 14 are respectively covered at the front and rear ends of each positioning block 41, a transverse through yielding gap 20 is reserved between the upper ends of the two anti-pinch covers 14, and the yielding gap 20 is positioned right above the positioning notch 10. Therefore, the positioning block 41 can be covered very well, and the semi-flexible coaxial line can be placed conveniently, so that the use is convenient.

As shown in fig. 3 and 5, the lower end of the anti-pinch cover 14 is limited by a vertical screw 141 or a vertical rivet, so that the rotation requirement of the anti-pinch cover 14 can be met.

As shown in fig. 3, the antenna production and assembly device further comprises a foot controller 5, and the left transverse pushing mechanism 2 and the right transverse pushing mechanism 3 are in control connection with the foot controller 5. The adoption of the foot controller 5 can facilitate the operation of a worker, thereby contributing to further improvement of the convenience of use.

As shown in fig. 3, 5 and 6, the foot controller 5 includes a foot switch 51 and a solenoid valve 52, wherein the solenoid valve 52 is disposed in the storage box 13, and controls and connects the left cylinder 21 and the right cylinder 31 with the solenoid valve 52, and also electrically connects the solenoid valve 52 with the foot switch 51. This not only facilitates the operation of assembling the antenna mount, but also provides shielding protection for the solenoid valve 52 to avoid interference of the solenoid valve 52 with the assembly operation and to reduce the chance of damage to the solenoid valve 52.

As shown in fig. 1, 10 to 12, one of the assembly flows of the antenna production and assembly device for assembling the WiFi antenna of the unmanned aerial vehicle is as follows:

first, simple assembly: firstly, the two rubber sleeves 104 are sleeved on the corresponding end parts of the positioning sleeve 101 and the corresponding end parts of the antenna adapter 103 in a non-complete sleeved mode, and then the positioning sleeve 101 and the antenna adapter 103 are sleeved on the two ends of the semi-flexible coaxial line 102 in a non-complete sleeved mode respectively; this results in a semi-finished antenna support.

Step two, pushing and assembling: firstly, placing the semi-flexible coaxial line 102 in the positioning notch 10, and enabling the sleeved port 110 of the positioning sleeve 101 to face the convex column part 23; then, the foot switch 51 is stepped down, and the left lateral pushing mechanism 2 and the right lateral pushing mechanism 3 are started simultaneously so as to enable the left pushing block 22 and the right pushing block 32 to move close to each other; along with the approaching of the left pushing block 22 and the right pushing block 32, the convex column part 23 is inserted into the sleeved port 110 of the positioning sleeve 101, and the right pushing block 32 is propped against the right end surface of the antenna adapter 103; then, as the left pushing block 22 and the right pushing block 32 continue to approach, the positioning sleeve 101 and the antenna adapter 103 complete the sleeving of the half-flexible coaxial cable 102; the two rubber sleeves 104 are contacted with the corresponding positioning blocks 41 and limited by the positioning blocks 41, so that the two rubber sleeves 104 can be accurately and stably sleeved at the connection part of the positioning sleeve 101 and the semi-flexible coaxial line 102 and the connection part of the antenna adapter 103 and the semi-flexible coaxial line 102. The assembly of the antenna stand 100 is completed, and the WiFi antenna of the unmanned aerial vehicle can be obtained by installing the antenna body 200.

In the simple assembly, the tight sleeve is not needed, so the assembly is very simple and convenient; in the pushing assembly process, a worker only needs to pedal the foot switch 51, and large labor force is not required. The antenna bracket can be positioned fast and accurately by the antenna production and assembly equipment, and the antenna bracket can be assembled fast and stably, so that the labor intensity of workers can be reduced, the assembly efficiency can be improved, and the assembly quality can be kept in a very high state for a long time.

Claims (10)

1. An antenna production equipment, its characterized in that: the positioning block body (4) is arranged between the left transverse pushing mechanism (2) and the right transverse pushing mechanism (3), and a positioning notch (10) which transversely penetrates through is formed in the positioning block body (4).

2. The antenna production and assembly apparatus of claim 1, wherein: the positioning seat body (1) comprises a base (11) and a wear-resistant table (12), the wear-resistant table (12) is arranged in the middle of the base (11), the left transverse pushing mechanism (2) and the right transverse pushing mechanism (3) are respectively arranged at the left end and the right end of the base (11), the movable end of the left transverse pushing mechanism (2) and the movable end of the right transverse pushing mechanism (3) are in sliding lap joint on the wear-resistant table (12), and the positioning block body (4) is arranged on the wear-resistant table (12).

3. The antenna production and assembly apparatus of claim 2, wherein: the bottom surface of the base (11) is provided with a storage box (13).

4. The antenna production and assembly apparatus of claim 1, wherein: the left transverse pushing mechanism (2) comprises a left air cylinder (21) and a left pushing block (22), wherein the left air cylinder (21) is transversely arranged at the left end of the positioning seat body (1) and enables the telescopic end of the left air cylinder (21) to face to the right, and the left pushing block (22) is arranged at the telescopic end of the left air cylinder (21).

5. The antenna production and assembly apparatus of claim 4, wherein: the right surface of the left pushing block (22) is provided with a convex column part (23).

6. The antenna production and assembly apparatus of claim 1, wherein: the right transverse pushing mechanism (3) comprises a right cylinder (31) and a right pushing block (32), wherein the right cylinder (31) is transversely arranged at the right end of the positioning seat body (1) and enables the telescopic end of the right cylinder (31) to face left, and the right pushing block (32) is arranged at the telescopic end of the right cylinder (31).

7. The antenna production and assembly apparatus of claim 1, wherein: the positioning block body (4) comprises at least one positioning block (41), and the positioning notch (10) transversely penetrates through the top of each positioning block (41); when the positioning blocks (41) are only one, the positioning blocks (41) can be detachably lapped on the positioning seat body (1); when more than two positioning blocks (41) are arranged, the positioning blocks (41) are transversely arranged side by side, positioning gaps (10) on the positioning blocks (41) are in butt joint communication, the positioning blocks (41) are detachably lapped on the positioning seat body (1), or one of the positioning blocks (41) is fixedly arranged on the positioning seat body (1), and the other positioning blocks (41) are detachably lapped on the positioning seat body (1).

8. The antenna production and assembly apparatus of claim 7, wherein: at least two positioning blocks (41) are arranged, an anti-pinch cover (14) is arranged on the positioning seat body (1), and the anti-pinch cover (14) covers each positioning block (41).

9. The antenna production and assembly apparatus of claim 8, wherein: the anti-pinch cover (14) is rotatably arranged on the positioning seat body (1) and enables the anti-pinch cover (14) to be separated from the positioning block (41) in a rotating mode.

10. The antenna production and assembly apparatus of claim 1, wherein: the device also comprises a pedal controller (5), wherein the left transverse pushing mechanism (2) and the right transverse pushing mechanism (3) are in control connection with the pedal controller (5).