CN213255413U - Novel crack waveguide antenna rubber coating equipment - Google Patents

Abstract

The utility model provides a novel crack waveguide antenna rubber coating equipment, include: the transmission mechanism is used for bearing the waveguide tube and enabling the waveguide tube to move at a constant speed along a preset direction; the gluing mechanism is used for gluing the waveguide tube; wherein, transport mechanism has the support frame, and rubber coating mechanism has the moulding piece, stores up gluey jar, and the moulding piece is fixed on the support frame to laminate mutually with the waveguide pipe, have along the T type of vertical direction running through this moulding piece and go out gluey mouth, store up gluey jar and moulding piece looks fixed connection for the storage glue solution has and cooperatees with advancing gluey hole and lets out the glue solution and flow in the play gluey hole of gluing of T shape play mouth, and the glue solution is gone out gluey mouthful even surface of drippage at the waveguide pipe from T type, thereby realizes the even rubber coating to the waveguide pipe.

Description

Novel crack waveguide antenna rubber coating equipment

Technical Field

The utility model belongs to the crack waveguide pipe field relates to a novel crack waveguide antenna rubber coating equipment.

Background

The slot waveguide antenna is used as a slot waveguide transmission line and is more and more widely applied to track traffic construction. Is made of an aluminum alloy waveguide material. Because the connection length of the slot waveguide antenna is hundreds of meters and is limited by processing cost, manual installation, vehicle length and the like, the length of the whole slot waveguide antenna is about 11 m. The surface of the slot waveguide antenna is provided with a plurality of slots which enable signals to be transmitted to the external space from the inside of the slot waveguide antenna, and in order to ensure the service performance of the product under various environmental requirements, a plurality of layers of protective measures need to be added on the slot surface of the waveguide antenna.

The protective measures are a plurality of wave-transparent protective layers, and specifically comprise a first protective layer composed of adhesive tapes, a second protective layer composed of glass fiber cloth and epoxy resin, and a third protective layer composed of protective paint. Wherein the first protective layer covers the plurality of cracks; the second protective layer covers the first protective layer; the third protective layer covers the second protective layer.

In the assembly process of the second protective layer, the mode adopted at present is bonding by manually mixing glue, the glue is coated on the fiber cloth through manual operation, and a small shovel is used for scraping and coating the glue uniformly, so that the operation difficulty is high, the operation is dependent on the skill and experience of an operator, and the stability and the consistency are poor. Once the coating is uneven or the glue content is insufficient, the phenomena of glue layer falling off and the like caused by the glue coating quality problem in the subsequent use process can be caused.

SUMMERY OF THE UTILITY MODEL

For solving the above problem, provide a can carry out the novel crack waveguide antenna rubber coating equipment of rubber coating operation to the wave guide automatically, the utility model discloses a following technical scheme:

the utility model provides a novel crack waveguide antenna rubber coating equipment, a serial communication port, include: the transmission mechanism is used for bearing the waveguide tube and enabling the waveguide tube to move at a constant speed along a preset direction; the gluing mechanism is used for gluing the waveguide tube; wherein, transport mechanism has the support frame, and the rubber coating mechanism has the moulding piece, stores up gluey jar, and the moulding piece is fixed on the support frame to laminate mutually with the waveguide pipe, have along the T type of vertical direction running through this moulding piece and go out gluey mouth, store up gluey jar and moulding piece looks fixed connection for the storage glue solution has and goes out gluey hole of letting the glue solution flow in T type play gluey mouth with T type play gluey mouth cooperatees.

The utility model provides a novel crack waveguide antenna rubber coating equipment can also have such characteristic, still includes: stop gear for carry on spacingly to the waveguide pipe that removes on transport mechanism, stop gear is the stopper of fixed connection on the support frame, and the stopper has along the at least a set of protruding group of vertical direction extension towards one side of waveguide pipe, and every protruding group of group includes two spacing archs, and the distance between the spacing arch equals with the width of waveguide pipe in every protruding group of group, and the waveguide pipe card is between two spacing archs that correspond.

The utility model provides a novel crack waveguide antenna rubber coating equipment, can also have such characteristic, wherein, transport mechanism still has the motor, drive assembly, a plurality of driving shafts and chain, motor fixed mounting is on the support frame, be connected with arbitrary one driving shaft through drive assembly, be used for driving this driving shaft and rotate, the driving shaft is rotationally installed on the support frame, be close to rubber coating mechanism, be used for bearing waveguide pipe and transmit the waveguide pipe through rotating, both ends fixed mounting at the driving shaft has the gear, the epaxial gear in each driving is connected through the chain, under the cooperation of gear and chain, all driving shafts are followed the driving shaft of being connected with the motor together and are rotated.

The utility model provides a novel crack waveguide antenna rubber coating equipment can also have such characteristic, and wherein, transport mechanism still has a plurality of driven shafts, and the driven shaft is rotatable installs on the support frame, is located the driving shaft in the ascending both sides of wave guide moving direction for the bearing wave guide, when the wave guide moved on driving shaft and driven shaft, the driving shaft drove the wave guide and removes, and furtherly, the wave guide drove the driven shaft and rotates.

The utility model provides a novel crack waveguide antenna rubber coating equipment can also have such characteristic, wherein, drive assembly includes the action wheel, from driving wheel and drive belt, the motor is connected with the action wheel and drives this action wheel and rotate, connect the one end at arbitrary one driving shaft from the driving wheel, rotate with this driving shaft together, the action wheel is connected through the drive belt with from the driving wheel for the action wheel drives and rotates from the driving wheel, further drives the driving shaft that corresponds and rotates.

The utility model provides a novel crack waveguide antenna rubber coating equipment can also have such characteristic, and wherein, the laminating face's of moulding plastics piece and wave guide both ends have the step that extends along the vertical direction, and the wave guide card is in the recess by the step formation, and distance between two steps equals with the width of wave guide.

The utility model provides a novel crack waveguide antenna rubber coating equipment can also have such characteristic, wherein, still possesses the length direction looks vertically sand grip with the step on the binding face, this sand grip be located T type go out glue mouthful with waveguide pipe moving direction the same one side, its height that highly is less than the step for the glue solution that will drip on the waveguide pipe evenly paints on waveguide pipe and binding face relative surface.

The utility model provides a novel crack waveguide antenna rubber coating equipment can also have such characteristic, and wherein, rubber coating mechanism still has the inserted sheet, and the moulding piece has and runs through this moulding piece and passes the inserted sheet mounting hole that the T type goes out the jiao kou along the horizontal direction, and the inserted sheet is inserted in the inserted sheet mounting hole for prevent the glue solution from flowing out from the T type goes out the jiao kou.

The utility model provides a novel crack waveguide antenna rubber coating equipment can also have such characteristic, and wherein, the storage is glued the jar and is wholly the back taper, and the top has the mouth of gluing down.

The utility model provides a novel crack waveguide antenna rubber coating equipment can also have such characteristic, and wherein, inserted sheet length direction's one end is provided with the drawing hole.

Utility model with the functions and effects

According to the utility model discloses a novel crack waveguide antenna rubber coating equipment, have the transport mechanism that is used for removing transmission to the waveguide pipe and carry out the rubber coating mechanism of rubber coating operation to the waveguide pipe, rubber coating mechanism glues the jar and carries out the rubber coating with the waveguide pipe laminating to the waveguide pipe including the storage that is used for saving the glue solution and glues the piece, it has the T type that lets the glue solution evenly drip on the piece to go out the jiao kou and passes the inserted sheet mounting hole that this T type goes out jiao kou to glue, the inserted sheet is inserted and can be prevented the glue solution from going out the jiao kou and flow in the inserted sheet mounting hole, after starting transport mechanism and removing transmission to the waveguide pipe, extract the inserted sheet from the inserted sheet mounting hole, the glue solution goes out the jiao kou from T type and evenly drips the surface at the waveguide pipe. According to the gluing equipment, glue solution is coated on the surface of the waveguide tube through the automatic equipment, the consistency and stability of the glue solution on the surface of the waveguide tube are improved, the uniformity of the glue solution on the surface of the waveguide tube is ensured, and the phenomenon that the glue layer falls off due to the fact that the glue solution is not uniformly coated is avoided.

Drawings

Fig. 1 is a schematic perspective view of a novel slot waveguide antenna gluing device in an embodiment of the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is one of the three-dimensional structures of the glue pressing block and the glue storage tank in the embodiment of the present invention;

FIG. 4 is a second three-dimensional structure diagram of the glue pressing block and the glue storage tank in the embodiment of the present invention;

FIG. 5 is one of the three-dimensional structures of the rubber-pressing block in the embodiment of the present invention;

fig. 6 is a second perspective view of the rubber pressing block according to the embodiment of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made with reference to the accompanying drawings and examples.

< example >

Fig. 1 is the utility model discloses an embodiment novel slot waveguide antenna rubber coating equipment's spatial structure sketch map. Fig. 2 is a partially enlarged view of a portion a in fig. 1.

As shown in fig. 1 and fig. 2, the present embodiment provides a novel slot waveguide antenna glue coating apparatus 100, which is used for performing a glue coating operation on a waveguide 200, and includes a conveying mechanism 10, a glue coating mechanism 20, and a limiting mechanism 30.

The transmission mechanism 10 is used for carrying the waveguide 200 and transmitting the waveguide 200, and includes a support frame 11, a motor 12, a transmission assembly 13, a driving shaft 14, a chain (not shown), and a driven shaft 15.

A support frame 11 is provided on the ground for supporting and mounting the various components of the gluing device 100.

The motor 12 is fixedly installed on the support frame 11, is located in the middle of the support frame 11, is connected with the driving shaft 14 through the transmission assembly 13, and is used for driving the driving shaft 14 to rotate. In this embodiment, the motor 12 can rotate forward and backward, so as to drive the driving shaft 14 to rotate forward and backward.

In this embodiment, the motor 12 is disposed parallel to the length direction of the supporting frame 11, and in other embodiments, the motor 12 may also be disposed perpendicular to the length direction of the supporting frame 11, and then transmits power to the driving shaft through the transmission assembly 13 engaged therewith.

The transmission assembly 13 has one end connected to the motor 12 and the other end connected to the driving shaft 14, and is used for transmitting power provided by the motor 12, and includes at least a driving wheel (not shown), a driven wheel 132 and a transmission belt 133. In this other embodiment, the transmission assembly 13 may further include a bevel gear or the like for performing transmission.

The driving wheel is connected with the motor 12 and rotates along with the motor 12. The driven pulley 132 is connected to one end of any one of the drive shafts 14 and rotates together with the drive shaft 14. The driving wheel is connected with the driven wheel 132 through a transmission belt, so that the driving wheel can drive the driven wheel 132 to rotate, and further drive the corresponding driving shaft 14 to rotate.

The driving shafts 14 are rotatably mounted on the supporting frame 11 for supporting the waveguide tubes 200 and transmitting the waveguide tubes 200 through rotation, gears are fixedly mounted at two ends of the driving shafts 14, the gears on the driving shafts 14 are connected through chains, and under the matching of the gears and the chains, all the driving shafts 14 rotate together along with the driving shafts 14 connected with the transmission assembly 13.

In this embodiment, the transmission mechanism 10 has 5 driving shafts 14, one of the driving shafts 14 is connected to the transmission assembly 13, and the other 4 driving shafts 14 rotate along with the driving shaft 14 connected to the transmission assembly 13 under the transmission of the chain.

The driven shaft 15 is rotatably installed on the support frame 11, located on both sides of the driving shaft 14 in the moving direction of the waveguide 200, and supports the waveguide 200. When the waveguide 200 moves on the driving shaft 14 and the driven shaft 15, the driving shaft 14 drives the waveguide 200 to move along the length direction of the supporting frame by the sliding friction force, and further, the waveguide 200 drives the driven shaft 15 to rotate by the sliding friction force.

The position limiting mechanism 20 is used to limit the position of the waveguide 200 on the transmission mechanism 10. In this embodiment, the limiting mechanism 20 is a limiting block fixedly connected to the support frame 11, and the limiting block is located on the support frame 11 and close to the driving shaft 14.

The stopper has along the at least a set of protruding group 21 of vertical direction extension towards one side of waveguide pipe 200, and every protruding group 21 of group includes two spacing archs 211, and the distance between the spacing archs 211 equals with waveguide pipe 200's width in every protruding group 21 of group, and waveguide pipe 200 card is between two corresponding spacing archs 211 to carry on spacingly to waveguide pipe 200, prevent that waveguide pipe from producing when moving along self length direction on transport mechanism and rocking.

In this embodiment, the stopper has 3 protruding groups 21 of group, consequently, can carry out spacing to 3 wave guide pipes 200 simultaneously, that is to say, can be simultaneously to 3 wave guide pipes on the transport mechanism and transmit.

The glue coating mechanism 30 is used for coating the waveguide 200 and has a glue storage tank 31, a glue pressing block 32 and an inserting piece 33.

Fig. 3 is one of the three-dimensional structures of the glue pressing block and the glue storage tank in the embodiment of the present invention. Fig. 4 is a second three-dimensional structure diagram of the glue pressing block and the glue storage tank in the embodiment of the present invention.

As shown in fig. 3 and 4, the glue storage tank 31 is fixedly connected to the gutta percha shell 32 for storing glue, and has a glue outlet (not shown) at the bottom for letting out the glue and a glue pouring port 311 at the top for pouring in the glue.

In this embodiment, the glue storage tank 31 is an inverted cone, and the square plane at the bottom is larger than the square plane at the top.

Fig. 5 is one of the three-dimensional structures of the rubber pressing block in the embodiment of the present invention. Fig. 6 is a second perspective view of the rubber pressing block according to the embodiment of the present invention.

As shown in fig. 5 and 6, the glue pressing block 32 is fixedly mounted on the supporting frame 11, is close to the driving shaft 14, is attached to the waveguide tube 200, and has a T-shaped glue outlet 321 penetrating through the glue pressing block 32 in the vertical direction and an insert mounting hole 322 penetrating through the glue pressing block 32 in the horizontal direction and penetrating through the T-shaped glue outlet 321.

The T-shaped glue outlet 321 is opposite to the glue outlet on the glue storage tank 31, and is used for allowing the glue solution in the glue storage tank 31 to drip on the surface of the waveguide tube 200.

In this embodiment, the length direction of the insertion piece mounting hole 322 is perpendicular to the length direction of the waveguide 200

The two ends of the abutting surface 32a of the waveguide 200 and the rubber block 32 have steps 323 extending in the vertical direction, the waveguide 200 is caught in the groove formed by the steps 323, and the distance between the two steps 323 is equal to the width of the waveguide 200. Meanwhile, the waveguide tube 200 is clamped in a groove formed by the steps 323 and corresponds to the protrusion group 21 on the limiting block, the waveguide tube 200 is clamped between the steps 323 and between the limiting protrusions 21, and the length direction of the waveguide tube is parallel to the length direction of the supporting frame.

The abutting surface 32a further has a convex strip 324 perpendicular to the longitudinal direction of the step 323. The protrusion 324 is located on the same side of the T-shaped glue outlet 321 as the moving direction of the waveguide 200, and the height of the protrusion is smaller than that of the step 323. After the glue solution drops from the T-shaped glue outlet 321 onto the surface of the waveguide 200 opposite to the bonding surface 32a, the waveguide 200 continues to move under the transmission of the transmission mechanism 10, and then the protruding strips 324 contact the glue solution on the waveguide 200 and uniformly coat the glue solution on the surface of the waveguide 200 opposite to the bonding surface 32 a.

As shown in fig. 3, the inserting sheet 33 is inserted into the inserting sheet mounting hole 322 for preventing the glue solution from flowing out from the T-shaped glue outlet 321. One end of the insertion piece 33 in the length direction is provided with a drawing hole 331 for a worker to poke the insertion piece 33 from the rubber press block 32.

In this embodiment, the number of the glue outlet tank 31, the glue pressing block 32 and the inserting pieces 33 in the gluing mechanism 30 is 3, that is, the gluing device 100 can simultaneously glue 3 waveguides.

The concrete process of gluing the waveguide tube 200 by using the novel slot waveguide antenna gluing device 100 of the embodiment is as follows:

in step S1, an appropriate amount of glue solution is poured into the glue storage tank 31.

In the initial state, the inserting sheet 33 is inserted into the inserting sheet mounting hole 322, the glue solution flows into the T-shaped glue outlet 321 of the glue pressing block 32 from the glue outlet of the glue storage tank 31, and the inserting sheet 33 blocks the T-shaped glue outlet 321, so that the glue solution does not drip from the T-shaped glue outlet 321.

In step S2, the waveguide 200 is placed on the transmission mechanism 10 with one end of the waveguide 200 on the driving shaft 14.

In step S3, the waveguide 200 is pushed under the plunger 32, so that the T-shaped plunger is caught between the steps 323 at both ends of the bonding surface 32a of the plunger 32.

In step S4, the inserting piece 33 is pulled out from the inserting piece mounting hole 322, so that the glue solution uniformly drops on the waveguide 200 from the T-shaped glue outlet 321.

The dropping speed and amount of the glue solution are related to the size of the T-shaped glue outlets 321, and the thickness of the glue solution applied on the waveguide tube 200 can be adjusted by using the T-shaped glue outlets 321 with different sizes.

Step S5, the motor 12 is started, the driving shaft 14 drives the waveguide 200 to move at a constant speed along the length direction of the motor 12, the glue solution continuously and uniformly drops on the waveguide 200 from the T-shaped glue outlet 321, and then the protruding strips 324 on the bonding surface 32a of the glue pressing block 32 uniformly apply the glue solution dropping on the waveguide 200 on the surface of the waveguide 200.

The thickness of the glue on the waveguide 200 is also related to the speed of movement of the waveguide 200, i.e. to the rotational speed of the motor 12. When the size of the T-shaped glue outlet 321 is not changed, the total amount of glue dripping on the waveguide 200 in unit time is not changed, and the faster the motor 12 rotates, the longer the distance the waveguide moves in unit time, so that the less glue is applied to the waveguide in unit area, and the thinner the thickness of the glue on the surface of the waveguide is.

Examples effects and effects

The novel crack waveguide antenna rubber coating equipment that this embodiment provided, have the transport mechanism that is used for removing transmission to the waveguide pipe and carry out the rubber coating mechanism of rubber coating operation to the waveguide pipe, rubber coating mechanism is including the storage that is used for saving the glue solution glue jar and carry out the rubber coating with the waveguide pipe laminating to the waveguide pipe and press the gluey piece, it goes out the jiao kou and passes this T type and goes out the inserted sheet mounting hole of gluing the mouth to have the T type that lets the glue solution evenly drip on the pressure gluey piece, the inserted sheet is inserted and can be prevented the glue solution from going out to flow in the jiao kou in the inserted sheet mounting hole, after starting transport mechanism and removing transmission to the waveguide pipe, extract the inserted sheet from the inserted sheet mounting hole, the glue solution goes out from the T type and glues the even surface that drips at. According to the gluing equipment, glue solution is coated on the surface of the waveguide tube through the automatic equipment, the consistency and stability of the glue solution on the surface of the waveguide tube are improved, the uniformity of the glue solution on the surface of the waveguide tube is ensured, and the phenomenon that the glue layer falls off due to the fact that the glue solution is not uniformly coated is avoided.

The novel crack waveguide antenna rubber coating equipment that this embodiment provided still has and carries out spacing stop gear to the waveguide pipe, because the whole length of waveguide pipe is longer, consequently when the waveguide pipe card between two spacing archs of stop gear, can prevent that the waveguide pipe from producing when removing along self length direction and rocking, provides the assurance for evenly scribbling the glue solution on the waveguide pipe surface.

The novel crack waveguide antenna rubber coating equipment that this embodiment provided, transport mechanism is including the motor that is used for providing power, carry out the transmission assembly that conveys with the power of motor, thereby be connected with transmission assembly and follow the motor and carry out pivoted driving shaft together and carry out rolling driven shaft when the wave guide removes, at the uniform velocity of motor under, the wave guide carries out uniform velocity rectilinear movement under the drive of driving shaft for the glue solution is evenly paintd on the wave guide surface.

The novel crack waveguide antenna rubber coating equipment that this embodiment provided, the both sides of the binding face of moulding the piece have the step, and the waveguide card still has on the binding face with step looks vertically sand grip in the recess that these two steps formed, this sand grip is located the moving direction of waveguide pipe in one side of T shape play jiao kou, can be with the even knife coating of glue solution on the waveguide pipe surface of drippage.

The above embodiments are merely illustrative of specific embodiments of the present invention, and the present invention is not limited to the description of the above embodiments.

Claims (10)

1. The utility model provides a novel slot waveguide antenna rubber coating equipment for carry out the rubber coating operation to the waveguide tube, a serial communication port, include:

the transmission mechanism is used for bearing the waveguide tube and enabling the waveguide tube to move at a constant speed along a preset direction; and

the gluing mechanism is used for gluing the waveguide tube;

wherein the conveying mechanism is provided with a supporting frame,

the glue coating mechanism is provided with a glue pressing block and a glue storage tank,

the glue pressing block is fixed on the support frame, is attached to the waveguide tube and is provided with a T-shaped glue outlet which penetrates through the glue pressing block along the vertical direction,

the glue storage tank is fixedly connected with the glue pressing block, is used for storing glue solution and is provided with a glue outlet hole which is matched with the T-shaped glue outlet to allow the glue solution to flow into the T-shaped glue outlet.

2. The novel slot waveguide antenna gumming device as claimed in claim 1, further comprising:

a limiting mechanism for limiting the waveguide tube moving on the transmission mechanism,

the limiting mechanism is a limiting block fixedly connected to the supporting frame, one side of the limiting block, facing the waveguide tube, is provided with at least one group of protrusion groups extending along the vertical direction, each group of protrusion group comprises two limiting protrusions, the distance between the limiting protrusions in each group of protrusion group is equal to the width of the waveguide tube,

the waveguide tube is clamped between the two corresponding limiting protrusions.

3. The novel slot waveguide antenna gluing device as claimed in claim 1, wherein:

wherein the transmission mechanism is also provided with a motor, a transmission component, a plurality of driving shafts and a chain,

the motor is fixedly arranged on the support frame, is connected with any one of the driving shafts through a transmission assembly and is used for driving the driving shaft to rotate,

the driving shaft is rotationally installed on the support frame, be close to rubber coating mechanism is used for the bearing waveguide pipe is right through rotating the waveguide pipe transmits the both ends fixed mounting of driving shaft has the gear, each epaxial gear of driving passes through the chain is connected the gear with under the cooperation of chain, all the driving shaft follow together with the motor is connected the driving shaft rotates together.

4. The novel slot waveguide antenna gluing device according to claim 3, wherein:

wherein the transmission mechanism is also provided with a plurality of driven shafts,

the driven shaft is rotatably arranged on the support frame, is positioned on two sides of the driving shaft in the moving direction of the waveguide tube and is used for supporting the waveguide tube,

when the waveguide tube moves on the driving shaft and the driven shaft, the driving shaft drives the waveguide tube to move, and further, the waveguide tube drives the driven shaft to rotate.

5. The novel slot waveguide antenna gluing device according to claim 3, wherein:

wherein the transmission assembly comprises a driving wheel, a driven wheel and a transmission belt,

the motor is connected with the driving wheel and drives the driving wheel to rotate,

the driven wheel is connected with one end of any one of the driving shafts and rotates together with the driving shaft,

the driving wheel and the driven wheel are connected through the transmission belt, so that the driving wheel drives the driven wheel to rotate, and further drives the corresponding driving shaft to rotate.

6. The novel slot waveguide antenna gluing device as claimed in claim 1, wherein:

wherein, two ends of the binding surface of the glue pressing block and the waveguide tube are provided with steps extending along the vertical direction, the waveguide tube is clamped in a groove formed by the steps,

the distance between the two steps is equal to the width of the waveguide.

7. The novel slot waveguide antenna gluing device as claimed in claim 6, wherein:

the joint surface is also provided with a convex strip which is vertical to the length direction of the step, the convex strip is positioned on one side of the T-shaped glue outlet, which is the same as the moving direction of the waveguide tube, the height of the convex strip is smaller than that of the step, and the convex strip is used for uniformly coating glue dropping on the waveguide tube on the surface, opposite to the joint surface, of the waveguide tube.

8. The novel slot waveguide antenna gluing device as claimed in claim 1, wherein:

wherein the glue coating mechanism is also provided with an inserting piece,

the glue pressing block is provided with an inserting piece mounting hole which penetrates through the glue pressing block along the horizontal direction and penetrates through the T-shaped glue outlet,

the inserting piece is inserted into the inserting piece mounting hole and used for preventing the glue solution from flowing out of the T-shaped glue outlet.

9. The novel slot waveguide antenna gluing device as claimed in claim 8, wherein:

wherein, the pull-out hole is arranged at one end of the inserting piece in the length direction.

10. The novel slot waveguide antenna gluing device as claimed in claim 1, wherein:

wherein, the glue storage tank is in an inverted cone shape, and the top of the glue storage tank is provided with a glue pouring opening.

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