CN111229953B

CN111229953B - Fin inserting assembly process of radiator shell for 5G base station

Info

Publication number: CN111229953B
Application number: CN202010093280.0A
Authority: CN
Inventors: 史沸涛; 楼林海; 周建; 成晓辉
Original assignee: Wuhu Jinyi Machinery Co ltd
Current assignee: Wuhu Jinyi Machinery Co ltd
Priority date: 2020-02-14
Filing date: 2020-02-14
Publication date: 2021-07-20
Anticipated expiration: 2040-02-14
Also published as: CN111229953A

Abstract

The invention discloses a fin inserting assembly process of a radiator shell for a 5G base station, relates to the technical field of communication, and comprises two loading and unloading operation stations. The invention adopts a split processing technology, thereby avoiding the phenomenon that the yield of products is reduced due to height change in an integral die-casting forming technology; but also greatly shortens the cooling time; the box body is arranged in the middle of the rack, the limiting mechanism is arranged on the box body, and the base body and the inserting fins are pressed in the area, so that semi-automation of equipment is realized, and the processing efficiency is improved; the top cutter is arranged in the mounting mechanism, and two groups of V-shaped blade sets which are symmetrically distributed are formed, so that the thickness of the inserted fin is sufficiently thin, the number of the inserted fins is remarkably increased in a certain forming range, and a better heat dissipation effect is realized; through set up reed and spacing bolt on the top sword, further guaranteed the structural strength and the radiating effect of product.

Description

Fin inserting assembly process of radiator shell for 5G base station

Technical Field

The invention relates to the technical field of communication, in particular to a fin inserting assembly process of a radiator shell for a 5G base station.

Background

The rapid development of the network communication technology enables people to come to the fifth generation mobile communication network, the 5G technology has super-large bandwidth, the data transmission rate is far higher than that of the previous network, and the experience rate can reach 1Gbps, which is equivalent to one hundred times of 4G; the 5G base station is a public mobile communication base station specially providing 5G network services to realize wireless signal transmission between a wired communication network and a wireless terminal, and with the increase of the 5G transmission rate by times, the 5G base station also processes mass data, so that the power consumption of processing equipment in the base station is greatly increased, and the heat production is inevitably increased.

At present, most of the existing radiators for 5G base stations are processed in an integral die-casting mode, and certain disadvantages are found in the long-term production and manufacturing process, such as: firstly, in order to meet a good heat dissipation effect, the shell of the heat radiator needs to be arranged in a deep manner, but the height reaches a certain degree, so that the yield of manufactured products is reduced; secondly, because the depth of the part is properly increased, the thickness of the radiating fins must be a certain thickness to meet the molding strength, but finally, because of the increase of the thickness, the number of the radiating fins in a certain molding range is reduced, and the radiating effect of the shell is poorer; thirdly, after the integral forming is finished, a large space is required to be occupied for cooling the integral forming, and the cooling time is too long; i arrange for solving above-mentioned technical problem, provide split type processing technology and come to process the radiator casing, but adopt aluminium argon arc to weld the artifical wing of inserting of welded mode, efficiency remains to promote, because it is big to insert the wing base number, adopts this kind of mode hardly to let each insert between the wing keep parallel in addition, in case take place the slope can lead to the ventilation effect variation, and the radiating effect is not good promptly.

Disclosure of Invention

The invention aims to provide a fin inserting assembly process of a radiator shell for a 5G base station, which aims to overcome the defects caused in the prior art.

A fin inserting assembly process of a radiator shell for a 5G base station comprises the following steps:

the method comprises the following steps: firstly, moving the mounting mechanism to a first station in the feeding direction through a conveying mechanism for feeding, and then abutting the adaptive inserting fin to the upper end of the top knife through a reed and a limiting bolt;

step two: placing the end face of the substrate with the slot downwards on the limiting column;

step three: starting a first air cylinder to drive the mounting mechanism positioned at the first station to move to the position under the limiting mechanism, moving the other mounting mechanism to the second station, and butting the matched inserting fin to the upper end of the top knife through the spring plate and the limiting bolt;

step four: then, opening a third air cylinder, and driving the second mounting seat to descend to the lowest point by the output end of the third air cylinder to limit the upper limit point of the base body in the assembling process;

step five: the second air cylinder is started, the output end of the second air cylinder drives the top knife to move upwards through the lower die holder and the mounting seat, the limiting column synchronously moves upwards to be matched with the second mounting seat to limit and fix the substrate, and meanwhile, the knife edge at the upper end of the top knife extrudes the hook-shaped end face of the inserting fin to expand the inserting fin in the inserting slot and realize riveting with the substrate;

step six: and returning to reset the third air cylinder and the second air cylinder, separating the upper die base from the lower die base, finishing the assembly process of the first station, returning to reset the air cylinders, and moving the assembled product to the discharge end of the first station to take out the product.

Preferably, the upper end of the rack is provided with two symmetrically arranged slide rails in the feeding direction, the conveying mechanism is slidably mounted on the slide rails and used for completing the feeding and discharging processes of products, the mounting mechanism is mounted at the upper end of the conveying mechanism and used for mounting the base body and the inserting wings, the side end of the conveying mechanism is provided with a controller at a position corresponding to the mounting mechanism, the lower end of the rack is fixed with a box body, the upper end of the box body is fixed with four symmetrically arranged support columns, the upper ends of the four support columns are fixed with a base plate, and the limiting mechanism is mounted on the lower end face of the base plate and used for limiting the riveting process of the base body and the inserting wings.

Preferably, conveying mechanism includes the connecting plate that cylinder one, gliding mass, fixed plate and two symmetries set up, cylinder one has two, and all installs in the upper end of box through the "L" shape mounting panel that two symmetries set up, still install the inductor on the mounting panel, the slider is installed to the output of cylinder one, the upper end of slider with the fixed plate links to each other, the gliding mass has the lower extreme that a plurality of and upper end all are fixed in the fixed plate, a plurality of the lower extreme slidable mounting of gliding mass is on the slide rail, two the both ends of connecting plate are fixed in respectively on the fixed plate that the symmetry set up.

Preferably, the mounting mechanism comprises a second cylinder, a lower die holder and a limiting column, the second cylinder is mounted at the lower end of the fixed plate, the output end of the second cylinder penetrates through the fixed plate and is connected with the lower end of the lower die holder, a plurality of symmetrically arranged guide sleeves are mounted on the lower die holder, a first mounting seat is further fixed on the lower die holder, a plurality of top knives with knife faces parallel and knife edges arranged upwards are fixed at the upper end of the first mounting seat, a long knife edge face and a short knife edge face are respectively arranged at two sides of the knife edge of each top knife, the inclination angles of the long knife edge face and the short knife edge face are both 60 degrees, one end of the short knife edge face is in contact with the side end of each inserted fin, the end face of each inserted fin is abutted against the knife edge of each top knife, a reed is fixed on the knife edge of each top knife, the reed is curved, the opening of each reed faces upwards, two symmetrically arranged limiting bolts are fixed at the side end of each top knife, the top knives form a blade group, and the blade group is symmetrically distributed in a V shape, the limiting column is provided with a plurality of circumferential symmetry arranged at the upper end of the first mounting seat, and the upper portion of the limiting column is arranged on an inclined plane.

Preferably, the limiting mechanism comprises a third cylinder, an upper die base and a second mounting base, the third cylinder is mounted on the lower end face of the base plate, two guide pillars which are symmetrically arranged are further fixed on the two sides of the third cylinder on the lower end face of the base plate, the upper end of the upper die base is connected with the output end of the third cylinder, the second mounting base is fixed at the lower end of the upper die base, the lower end face of the second mounting base is matched with the upper surface of the base body, and a plurality of guide rods matched with the guide sleeves are further circumferentially fixed at the lower end of the upper die base.

Preferably, the upper end of the inserting fin is in a hook shape and is abutted to the knife edge of the top knife, the lower end of the inserting fin is clamped between the knife surface of the top knife and the spring leaf, and the side ends of the inserting fin are abutted to the two symmetrically arranged limiting bolts.

Preferably, the side end of the base body is arranged on the limiting column through an inclined surface on the limiting column, and the upper end of the base body is provided with a slot matched with the hook-shaped upper end of the inserting fin.

The invention has the advantages that:

(1) by adopting a split processing technology, the phenomenon that the yield of products is reduced due to height change in an integral die-casting forming technology is avoided; and only need to cool off the base member can, the cooling volume diminishes, can also shorten the cooling time greatly when having realized that occupation space reduces.

(2) Through setting up the box in the middle of the frame and set up stop gear on the box, carry out the riveting of base member and inserted wing in this region, before the feeding, after the ejection of compact respectively with the pressfitting process formation duplex position's processing mode, realized the semi-automatization of equipment, improved machining efficiency.

(3) The top knife is arranged in the mounting mechanism, and two groups of V-shaped blade sets which are symmetrically distributed are formed, so that the fixing effect of the inserted fin riveted in the slot is ensured, the structural strength of a product is still ensured, the thickness of the inserted fin is thin enough, the quantity is obviously increased in a certain forming range, and a better heat dissipation effect is realized.

(4) Through set up reed and spacing bolt on the top sword, can prevent to insert the wrong phenomenon of inserting because of inserting the wing size difference, can also guarantee to insert the wing and can keep parallel state inserting process and pressfitting process homoenergetic, further guaranteed the structural strength and the radiating effect of product.

Drawings

FIG. 1 is a process flow diagram of the present invention.

Fig. 2 is a schematic structural diagram of the present invention.

Fig. 3 is a front view of the present invention.

Fig. 4 is a schematic structural view of the conveying mechanism of the present invention.

FIG. 5 is a schematic structural diagram of the mounting mechanism of the present invention.

Fig. 6 is a schematic structural view of the limiting mechanism of the present invention.

FIG. 7 is a schematic view of the assembly of the insertion fin and the top blade of the present invention.

Fig. 8 is a schematic structural view of the top cutter of the present invention.

FIG. 9 is a schematic view of the structure of the substrate in the present invention.

The device comprises a rack 1, a base 2, a base 3, a fin inserting mechanism 4, a conveying mechanism 5, a mounting mechanism 6, a limiting mechanism 7, a sliding rail 8, a controller 9, a box body 10, a supporting column 11, a base plate 201, a slot 401, a cylinder I, a sliding body 402, a fixing plate 403, a connecting plate 404, a mounting plate 405, a sensor 406, a sliding block 407, a cylinder II 501, a lower die holder 502, a limiting column 503, a guide sleeve 504, a mounting seat I505, a top knife 506, a reed 507, a limit bolt 508, a cylinder III 602, an upper die holder 603, a mounting seat II, a guide column 604 and a guide rod 605.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1 to 9, the fin inserting assembly process of the radiator housing for the 5G base station comprises a frame 1, a base body 2, an inserting fin 3, a conveying mechanism 4, an installing mechanism 5 and a limiting mechanism 6.

It should be noted that there are two installation mechanisms 5, and the specifications are the same, and the two sides of the box 9 on the rack 1 in the feeding direction are divided into a first station and a second station.

In this embodiment, two symmetrically arranged slide rails 7 are installed at the upper end of the rack 1 in the feeding direction, the conveying mechanism 4 is slidably installed on the slide rails 7 and used for completing the feeding and discharging processes of a product, the installation mechanism 5 is installed at the upper end of the conveying mechanism 4 and used for installing the base body 2 and the insertion fins 3, the controller 8 is installed at the side end of the conveying mechanism 4 at the position corresponding to the installation mechanism 5, the lower end of the rack 1 is fixed with the box body 9, the upper end of the box body 9 is fixed with four symmetrically arranged support columns 10, the upper ends of the four support columns 10 are fixed with the base plate 11, the limiting mechanism 6 is installed on the lower end face of the base plate 11 and used for limiting the pressing process of the base body 2 and the insertion fins 3

In this embodiment, the conveying mechanism 4 includes a first air cylinder 401, a sliding body 402, a fixing plate 403 and two connecting plates 404 symmetrically arranged, the first air cylinder 401 has two, and is installed at the upper end of the box 9 through two symmetrically arranged "L" -shaped installation plates 405, an inductor 406 is further installed on the installation plates 405, a slider 407 is installed at the output end of the first air cylinder 401, the upper end of the slider 407 is connected with the fixing plate 403, the sliding body 402 has a plurality of upper ends, the upper ends of the sliding bodies are all fixed at the lower end of the fixing plate 403, the lower ends of the sliding bodies 402 are slidably installed on the slide rail 7, and two ends of the two connecting plates 404 are respectively fixed at the symmetrically arranged fixing plates 403.

It should be noted that the first air cylinder 401 is a rodless air cylinder, a PLC controller is installed inside the box 9, a start button, a pause button, an emergency stop button and a plug wire connector are installed in the controller 8, and the controller 8 does not touch the surface of the support column 10 in the process of moving along with the conveying mechanism 4.

In this embodiment, the mounting mechanism 5 includes a second air cylinder 501, a lower die holder 502 and a limiting column 503, the second air cylinder 501 is mounted at the lower end of a fixing plate 403, the output end of the second air cylinder 501 penetrates through the fixing plate 403 and is connected with the lower end of the lower die holder 502, the lower die holder 502 is mounted with a plurality of symmetrically arranged guide sleeves 504, a first mounting seat 505 is further fixed on the lower die holder 502, the upper end of the first mounting seat 505 is fixed with a plurality of top knives 506 with knife faces parallel and with upward knife edges, the two sides of the knife edge of the top knife 506 are respectively a long knife edge face and a short knife edge face, the inclination angles of the long knife edge face and the short knife edge face are both 60 °, one end of the short knife edge face is in contact with the side end of the plug fin 3, the end face of the plug fin 3 abuts against the knife edge of the top knife 506, a reed 507 is fixed on the knife face of the top knife 506, the reed 507 is curved and has an upward opening, two symmetrically arranged limiting bolts 508 are fixed on the side end of the top knife 506, the top knives 506 form a blade group, the blade group is divided into two groups and symmetrically distributed in a V shape, the limiting columns 503 are arranged at the upper ends of the first mounting seats 505 in a circumferential symmetric mode, and the upper portions of the limiting columns 503 are arranged on inclined planes.

In this embodiment, the limiting mechanism 6 includes a third cylinder 601, an upper mold base 602, and a second mounting base 603, where the third cylinder 601 is mounted on the lower end surface of the substrate 11, two symmetrically arranged guide pillars 604 are further fixed on two sides of the third cylinder 601 on the lower end surface of the substrate 11, the upper end of the upper mold base 602 is connected to the output end of the third cylinder 601, the second mounting base 603 is fixed to the lower end of the upper mold base 602, the lower end surface of the second mounting base 603 is matched with the upper surface of the base 2, and a plurality of guide rods 605 matched with the guide sleeves 504 are further circumferentially fixed to the lower end of the upper mold base 602.

It should be noted that the edge of the inner hole at the upper end of the guide sleeve 504 is rounded, and the lower end of the guide rod 605 is also rounded, that is, the guide rod 605 can smoothly move downward into the guide sleeve 504.

It is worth noting that the upper end of the inserting fin 3 is in a hook shape and is abutted against the edge of the top cutter 506, the lower end of the inserting fin 3 is clamped between the cutter surface of the top cutter 506 and the spring sheet 507, and the side ends of the inserting fin 3 are abutted against two symmetrically arranged limit bolts 508.

In addition, the side end of the base body 2 is arranged on the limit column 503 through the inclined surface on the limit column 503, and the upper end of the base body 2 is provided with a slot 201 matched with the hook-shaped upper end of the inserting fin 3.

The working process and principle are as follows: when the invention is used, the concrete operation steps are as follows,

the method comprises the following steps: firstly, an operator stands at two ends of the frame 1, namely two sides of the limiting mechanism 6, so that the limiting mechanism 6 is ensured not to generate interference in the process of installing the base body 2 and the inserting fins 3, and the inserting fins 3 which are selected and adapted are abutted against the upper end of the top knife 506 through the reeds 507 and the limiting bolts 508;

step two: then the base body 2 is placed on the limiting columns 503, in the process, the end face with the slot 201 on the base body 2 needs to be placed downwards, and the base body 2 can be guaranteed to be clamped in a plurality of circumferentially arranged limiting columns 503 under the condition that the upper ends of the limiting columns 503 are obliquely arranged and the self gravity of the base body 2;

step three: then, a starting button is pressed, a command signal is transmitted to a PLC (programmable logic controller), the PLC controls a first cylinder 401 to be started according to the received signal, the output end of the first cylinder drives an installation mechanism 5 to move to the position under a limiting mechanism 6 through a sliding block 407 and a fixing plate 403, at the moment, the other installation mechanism 5 moves to a second station, and the matched inserting fin 3 is abutted to the upper end of a top knife 506 through a reed 507 and a limiting bolt 508;

step four: after the sensor 406 senses a signal, the PLC controller also controls the cylinder III 601 to be started, the output end of the cylinder III descends until the lowest point, and the upper limit point of the base body 2 in the assembling process is limited;

step five: starting a second air cylinder 501, driving a top cutter 506 to move upwards through a lower die holder 502 and a first mounting seat 505 at the output end of the second air cylinder, realizing the limiting fixation of the substrate 2 by the synchronous ascending of a limiting column 503 and the matching of a second mounting seat 603, and extruding the hook-shaped end face of the insertion fin 3 by the upper end cutter edge of the top cutter 506 so as to expand in the slot 201 and realize riveting with the substrate 2;

step six: and returning and resetting the third cylinder 601 and the second cylinder 501, separating the upper die base 602 from the lower die base 502, finishing the assembly process of the first station, returning and resetting the first cylinder 401, and moving the assembled product to the discharge end of the first station to be taken out.

Based on the above, the split type processing technology is adopted, so that the phenomenon that the yield of products is reduced due to height change in the integral die-casting forming technology is avoided; only the substrate 2 needs to be cooled, so that the cooling volume is reduced, the occupied space is reduced, and the cooling time can be greatly shortened; the box body 9 is arranged in the middle of the rack 1, the limiting mechanism 6 is arranged on the box body 9, the riveting of the base body 2 and the inserting wings 3 is carried out in the area, and a double-station processing mode is formed with the riveting process before feeding and after discharging, so that the semi-automation of equipment is realized, and the processing efficiency is improved;

the top knife 506 is arranged in the mounting mechanism 5, and two groups of V-shaped blade sets which are symmetrically distributed are formed, so that the fixing effect that the inserting fin 3 is riveted in the slot 201 is ensured, the structural strength of a product is still ensured, and the thickness of the inserting fin 3 is enough thin, so that the number of the inserting fins arranged in a certain forming range is remarkably increased, and a better heat dissipation effect is realized; through set up reed 507 and stop cock 508 on top sword 506, can prevent to insert the wrong phenomenon of appearance because of inserting the wing 3 size difference, can also guarantee to insert the wing and can keep parallel state at insertion process and pressfitting process homoenergetic, further guaranteed the structural strength and the radiating effect of product.

It will be appreciated by those skilled in the art that the invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The embodiments disclosed above are therefore to be considered in all respects as illustrative and not restrictive. All changes which come within the scope of or equivalence to the invention are intended to be embraced therein.

Claims

1. A fin inserting assembly process of a radiator shell for a 5G base station is characterized by comprising the following steps:

the method comprises the following steps: firstly, the mounting mechanism (5) is moved to a first station in the feeding direction through the conveying mechanism (4) for feeding, and then the adaptive inserting fin (3) is abutted to the upper end of the top knife (506) through a reed (507) and a limiting bolt (508);

step two: the end face of the base body (2) with the slot (201) faces downwards and is placed on the limiting column (503);

step three: opening a first air cylinder (401) to drive the mounting mechanism (5) located at the first station to move to the position under the limiting mechanism (6), moving the other mounting mechanism (5) to the second station, and enabling the adaptive inserting fin (3) to abut against the upper end of the top knife (506) through a reed (507) and a limiting bolt (508) in the same way;

step four: then, the third cylinder (601) is started, the output end of the third cylinder drives the second mounting seat (603) to move downwards to the lowest point, and the upper limit point of the base body (2) in the assembling process is limited;

step five: starting a second air cylinder (501), driving a top cutter (506) to move upwards by an output end of the second air cylinder through a lower die holder (502) and a first mounting seat (505), realizing the limiting and fixing of the base body (2) by the synchronous ascending of a limiting column (503) and the matching of a second mounting seat (603), and extruding the hook-shaped end face of the insertion fin (3) by an upper end knife edge of the top cutter (506) to expand in the slot (201) and realize riveting with the base body (2);

step six: and returning and resetting the third cylinder (601) and the second cylinder (501), separating the upper die base (602) from the lower die base (502), finishing the assembling process of the first station, returning and resetting the first cylinder (401), and moving the assembled product to the discharge end of the first station to take out the product.

2. The fin inserting assembly process of the radiator shell for the 5G base station, according to claim 1, is characterized in that: two symmetrically arranged slide rails (7) are arranged at the upper end of the frame (1) in the feeding direction, the conveying mechanism (4) is slidably arranged on the slide rails (7), and is used for completing the feeding and discharging process of the product, the mounting mechanism (5) is mounted at the upper end of the conveying mechanism (4), and is used for mounting the base body (2) and the inserting fins (3), a controller (8) is mounted at the side end of the conveying mechanism (4) at the position corresponding to the mounting mechanism (5), a box body (9) is fixed at the lower end of the frame (1), four symmetrically arranged supporting columns (10) are fixed at the upper end of the box body (9), a base plate (11) is fixed at the upper ends of the four supporting columns (10), the limiting mechanism (6) is arranged on the lower end surface of the base plate (11), and is used for limiting the riveting process of the base body (2) and the inserting fin (3).

3. The fin inserting assembly process of the radiator shell for the 5G base station, according to claim 1, is characterized in that: conveying mechanism (4) are including cylinder (401), sliding body (402), fixed plate (403) and connecting plate (404) that two symmetries set up, cylinder (401) have two, and all install in the upper end of box (9) through "L" shape mounting panel (405) that two symmetries set up, still install inductor (406) on mounting panel (405), slider (407) are installed to the output of cylinder (401), the upper end of slider (407) with fixed plate (403) link to each other, sliding body (402) have a plurality of and the upper end all be fixed in the lower extreme of fixed plate (403), a plurality of lower extreme slidable mounting of sliding body (402) is on slide rail (7), two the both ends of connecting plate (404) are fixed in respectively on fixed plate (403) that the symmetry set up.

4. The fin inserting assembly process of the radiator shell for the 5G base station, according to claim 1, is characterized in that: the mounting mechanism (5) comprises a second cylinder (501), a lower die holder (502) and a limiting column (503), the second cylinder (501) is mounted at the lower end of the fixing plate (403), the output end of the second cylinder (501) penetrates through the fixing plate (403) and is connected with the lower end of the lower die holder (502), a plurality of guide sleeves (504) which are symmetrically arranged are mounted on the lower die holder (502), a first mounting seat (505) is further fixed on the lower die holder (502), a plurality of top knives (506) with knife faces parallel and with knife edges upward are fixed at the upper ends of the first mounting seat (505), long knife edges and short knife edges are respectively arranged on two sides of the knife edges of the top knives (506), the inclination angles of the long knife edges and the short knife edges are both 60 degrees, one ends of the short knife edges are in contact with the side ends of the inserting wings (3), the end faces of the inserting wings (3) are abutted against the knife edges of the top knives (506), and reeds (507) are fixed on the knife faces of the top knives (506), reed (507) are curved shape and the opening up, and the side of top sword (506) is fixed with two spacing bolts (508) that the symmetry set up, a plurality of top sword (506) form the blade group, the blade group has two sets ofly and is "V" shape symmetric distribution, spacing post (503) have a plurality of and circumference symmetry set up in the upper end of mount pad one (505), a plurality of the upper portion of spacing post (503) is the inclined plane setting.

5. The fin inserting assembly process of the radiator shell for the 5G base station as claimed in claim 4, wherein the fin inserting assembly process comprises the following steps: the limiting mechanism (6) comprises a third cylinder (601), an upper die base (602) and a second mounting base (603), the third cylinder (601) is mounted on the lower end face of the base plate (11), two guide posts (604) which are symmetrically arranged are further fixed on the two sides of the third cylinder (601) on the lower end face of the base plate (11), the lower ends of the two guide posts (604) are connected to the upper die base (602) and the second mounting base (603) in a sliding mode, the upper end of the upper die base (602) is connected with the output end of the third cylinder (601), the second mounting base (603) is fixed at the lower end of the upper die base (602), the lower end face of the second mounting base (603) is matched with the upper surface of the base body (2), and a plurality of guide rods (605) matched with the guide sleeve (504) are further circumferentially fixed at the lower end of the upper die base (602).

6. The fin inserting assembly process of the radiator shell for the 5G base station, according to claim 1, is characterized in that: the upper end of each insertion fin (3) is in a hook shape, the end face of each hook shape abuts against the edge of the corresponding top cutter (506), the lower end of each insertion fin (3) is clamped between the cutter face of the corresponding top cutter (506) and the corresponding reed (507), and the side end of each insertion fin (3) abuts against the inner sides of the two symmetrically-arranged limiting bolts (508).

7. The fin inserting assembly process of the radiator shell for the 5G base station, according to claim 1, is characterized in that: the side end of the base body (2) is arranged on the limiting column (503) through an inclined surface on the limiting column (503), and the upper end of the base body (2) is provided with a slot (201) matched with the hook-shaped upper end of the inserting wing (3).