CN217834701U - LET network signal sharing transmitter shell correction tool - Google Patents

Abstract

The application provides a tool is rectified to LET network signal sharing transmitter shell, including workstation, frame and at least 2 group correction modules, rectify the module and install in the frame, the rack-mount is on the workstation, rectify the module including rectifying cylinder, lifter plate, guide pillar subassembly and correction drift subassembly, rectify the drift subassembly and install on the lifter plate, the lifter plate passes through the guide pillar subassembly and installs in the frame, it can drive the lifter plate and move the correction drift subassembly and be elevating movement to rectify the cylinder. This application has cancelled artifical manual correction to the shell to great improvement correction efficiency, still reduced workman's intensity of labour.

Description

LET network signal sharing transmitter shell correction tool

Technical Field

The application relates to LET network signal sharing transmitter shell detection field, in particular to LET network signal sharing transmitter shell correction jig.

Background

ET means 4G network. In brief, 4G network refers to 4G network, and the whole course is the fourth generation mobile communication and its technology. The 4GLET network has the greatest characteristic of greatly improving the internet surfing speed, and can bring the extreme internet surfing experience to users. The full name of LTE is "Longterm Evolution", which translates to "long-range Evolution". The LTE is divided into two duplex modes, namely FDDLTE and TDDLTE, the LTE obviously increases the spectrum efficiency and the data transmission rate, and the peak rate can reach 50Mbps in uplink and 100Mbps in downlink. Compared with the 3G era, the speed is improved by 10 times by the downlink peak value of 10 Mbps.

The LET network signal sharing transmitter in the prior art is that an antenna is separated from a transmitter, the transmitter is in a box shape and is connected through a feeder line, and in order to reduce the routing signal consumption, the transmitter is arranged below or beside the antenna. After the shell of the emitter is injection-molded, if the shell deforms in the width direction, the deformation of the box body in the width direction is repaired by using a traditional manual correction tool all the time, and the emitter has the defects of certain potential safety hazard in operation and low working efficiency.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a can automatic correction LET network signal sharing transmitter shell's tool.

In order to achieve the above purpose, the present application provides the following technical solutions:

the utility model provides a tool is rectified to LET network signal sharing transmitter shell, includes workstation, frame and at least 2 groups correction module, rectify the module and install in the frame, the rack-mount is on the workstation, rectify the module including rectifying cylinder, lifter plate, guide pillar subassembly and correction drift subassembly, rectify the drift subassembly and install on the lifter plate, the lifter plate passes through the guide pillar subassembly and installs in the frame, it drives the lifter plate and moves correction drift subassembly and be elevating movement to rectify the cylinder.

Furthermore, the correction module comprises a correction driving block, a first correction sliding block and a second correction sliding block, a first inclined plane and a second inclined plane are respectively arranged on two sides of the correction driving block, the first correction sliding block is installed on the first inclined plane through a first return spring assembly and can move up and down along the first inclined plane, and the second correction sliding block is installed on the second inclined plane through a second return spring assembly and can move up and down along the second inclined plane.

Furthermore, the first correcting slide block is provided with a third inclined surface corresponding to the first inclined surface, and when the first correcting slide block moves upwards along the first inclined surface through the third inclined surface, the first correcting slide block moves away from the correcting driving block.

Furthermore, the second correcting slide block is provided with a fourth inclined surface corresponding to the second inclined surface, and when the second correcting slide block moves upwards along the first inclined surface through the fourth inclined surface, the second correcting slide block moves away from the correcting driving block.

Furthermore, the correction module further comprises a resetting device for resetting the first correction slide block and the second correction slide block.

Further, the resetting device comprises a limiting strip, a first resetting spring, a second resetting spring, a first mounting block and a second mounting block, a first limiting through groove is formed in the transverse direction of the first correcting slider, a second limiting through groove is formed in the transverse direction of the second correcting slider, the limiting strip is transversely mounted on the correcting driving block, one end of the limiting strip is inserted into the first limiting through groove, the other end of the limiting strip is inserted into the second limiting through groove, a first circular hole is formed in the first limiting through groove in a vertically downward penetrating mode through the first correcting slider, the first resetting spring penetrates through the first circular hole, the upper end of the first resetting spring is abutted against the bottom of the limiting strip, the lower end of the first resetting spring is abutted against the upper surface of the first mounting block, the first mounting block is mounted at the bottom of the first correcting slider, a second circular hole is formed in the second limiting through groove in a vertically downward penetrating mode through the second correcting slider, the second resetting spring penetrates through the second circular hole, the upper end of the second resetting spring is abutted against the bottom of the second limiting strip, the lower end of the second resetting spring is abutted against the upper surface of the second correcting slider, and the mounting block is mounted at the upper surface of the second correcting slider.

Furthermore, a first avoiding groove is formed in the outer side face of the second correcting sliding block, and a second avoiding groove is formed in the outer side face of the second mounting block.

Furthermore, a positioning block is arranged on the workbench corresponding to the correction module group and used for positioning the shell.

The beneficial effect of this application does:

this application is through setting up the correction module, when the inboard side of the width of shell is proofreaied and correct as required, at first carry out the bulk heating to the shell, place it on the workstation after the heating, then correct cylinder drive correction drift subassembly and descend, correct the drift subassembly and descend the back, press on the inboard bottom surface of shell through the bottom of proofreaying the drift subassembly earlier, the both sides motion of the width direction of proofreaying the drift subassembly looks shell at last, thereby proofreaies and correct the shell, let originally correct with shell bottom surface vertically state at the side of the inside sunken shell of width direction, this application has cancelled artifical manual correction to the shell, thereby great improvement the correction efficiency, workman's intensity of labour has still been reduced.

Drawings

Fig. 1 is a schematic structural diagram of a calibration fixture for a LET network signal sharing transmitter housing according to an embodiment of the present application;

fig. 2 is a schematic structural diagram of a calibration module of a calibration fixture for a LET network signal sharing transmitter housing according to an embodiment of the present application;

fig. 3 is a cross-sectional view of a calibration module of a LET network signal sharing transmitter housing calibration fixture according to an embodiment of the present application;

fig. 4 is a schematic structural diagram of a calibration module of a calibration fixture for a LET network signal sharing transmitter housing according to an embodiment of the present application;

description of reference numerals:

1, a workbench; 2. a frame; 3. a correction module;

31. a correction cylinder; 32. a lifting plate; 33. a guide post assembly; 34. a corrective punch assembly;

341. correcting the driving block; 342. a first correcting slider; 343. a second correction slider; 344. a first return spring assembly; 345. a second return spring assembly; 346. a resetting device;

341a, a first inclined plane; 341b, a second slope;

342a, a third bevel; 342b, a fourth bevel;

3461. a limiting strip; 3462. a first return spring; 3463. a second return spring; 3464. a first mounting block; 3465. a second mounting block; 3466. a first limit through groove; 3467. a second limiting through groove; 3468. a first circular hole; 3469. a second circular hole;

342c, a first avoiding groove; 342d, a second avoiding groove;

Detailed Description

The terminology used in the description of the embodiments of the present application is for the purpose of describing particular embodiments of the present application only and is not intended to be limiting of the application, as the embodiments of the present application will be described in detail below with reference to the accompanying drawings.

As shown in fig. 1, a calibration jig for a shell of an LET network signal sharing transmitter includes a workbench 1, a rack 2 and at least 2 sets of calibration modules 3, each calibration module 3 is installed on the rack 2, the rack 2 is installed on the workbench 1, each calibration module 3 includes a calibration cylinder 31, a lifting plate 32, a guide pillar assembly 33 and a calibration punch assembly 34, the calibration punch assembly 34 is installed on the lifting plate 32, the lifting plate 32 is installed on the rack 2 through the guide pillar assembly 33, and the calibration cylinder 31 can drive the lifting plate 32 to drive the calibration punch assembly 34 to perform lifting movement.

This application is through setting up correction module 3, when the inboard side of the width of shell is rectified to needs, at first carry out the bulk heating to the shell, place it on the workstation after the heating, then correction cylinder 31 drive correction drift subassembly 34 descends, earlier press on the inboard bottom surface of shell through the bottom of correcting drift subassembly 34, the both sides motion of the width direction of the 34 looks shells of final correction drift subassembly, thereby rectify the shell, let originally rectify with shell bottom surface vertically state at the side of the inside sunken shell of width direction, this application has cancelled artifical manual correction to the shell, thereby great improvement correction efficiency, workman's intensity of labour has still been reduced.

In this embodiment, the calibration module 3 includes a calibration driving block 341, a first calibration slider 342 and a second calibration slider 343, a first inclined plane 341a and a second inclined plane 341b are respectively disposed on two sides of the calibration driving block 341, the first calibration slider 342 is mounted on the first inclined plane 341a through a first return spring component 344 and can move up and down along the first inclined plane 341a, and the second calibration slider 343 is mounted on the second inclined plane 341b through a second return spring component 345 and can move up and down along the second inclined plane 341 b.

The first return spring assembly 344 is respectively disposed at the front side and the rear side of the correction driving block 341 and the first correction slider 342, one end of the first return spring assembly 344 is mounted on the correction driving block 341, and the other end of the first return spring assembly 344 is mounted on the first correction slider 342, so that the first correction slider 342 can be pulled toward the correction driving block 341 to prevent the first correction slider 342 from moving outward, and the first return spring assembly 344 does not affect the ascending and descending movement of the first correction slider 342, which is inclined along the first inclined surface 341 a.

In this embodiment, the first calibration slider 342 is provided with a third inclined surface 342a corresponding to the first inclined surface 341a, and when the first calibration slider 342 moves upward along the first inclined surface 341a via the third inclined surface 342a, the first calibration slider 342 moves away from the calibration driving block 341.

In this embodiment, the second correction slider 343 is provided with a fourth inclined surface 342b corresponding to the second inclined surface 341b, and when the second correction slider 343 moves upward along the first inclined surface 341a via the fourth inclined surface 342b, the second correction slider 343 moves away from the correction driving block 341.

In this embodiment, the calibration module 3 further includes a reset device 346 for resetting the first calibration slider 342 and the second calibration slider.

In this embodiment, the returning device 346 includes a limiting bar 3461, a first returning spring 3462, a second returning spring 3463, a first mounting block 3464 and a second mounting block 3465, a first limiting through groove 3466 is formed in the lateral direction of the first correcting slider 342, a second limiting through groove 3467 is formed in the lateral direction of the second correcting slider 343, the limiting bar 3461 is transversely mounted on the correcting driving block 341, one end of the limiting bar 3461 is inserted into the first limiting through groove 3466, the other end of the limiting bar 3461 is inserted into the second limiting through groove 3467, a first circular hole 3468 is formed in the first limiting through groove 3466 and vertically penetrates through the first correcting slider 342, the first returning spring 3462 penetrates through the first circular hole 3468, the upper end of the first returning spring 3461 abuts against the bottom of the limiting bar 3461, the lower end of the first returning spring 3462 abuts against the upper surface of the first mounting block 3464, the first mounting block 3464 is mounted at the bottom of the first correcting slider 342, the second returning spring 3463 penetrates through the second limiting through groove 3463 and vertically penetrates through 3263 and vertically penetrates through the lower end of the second correcting slider 3463 and vertically penetrates through 3265 and the second returning spring 3463 and the lower end of the second correcting slider 3465.

In this embodiment, the outer side surface of the second calibration slider 343 has a first avoiding groove 342c, the outer side surface of the second mounting block 3465 has a second avoiding groove 342d, and the first avoiding groove 342c and the second avoiding groove 342d are configured to avoid the reinforcing ribs on the inner side surface of the housing.

In this embodiment, the workbench is provided with a positioning block corresponding to the correction module 3, and the positioning block is used for positioning the housing.

In the description of the embodiments of the present application, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly and may include, for example, a fixed connection, an indirect connection through an intermediate medium, a connection between two elements, or an interaction between two elements. The specific meanings of the above terms in the embodiments of the present application can be understood by those of ordinary skill in the art according to specific situations.

Reference throughout this specification to apparatus or components, in embodiments or applications, means or components must be constructed and operated in a particular orientation and therefore should not be construed as limiting the present embodiments. In the description of the embodiments of the present application, "a plurality" means two or more unless specifically stated otherwise.

The terms "first," "second," "third," "fourth," and the like in the description and in the claims of the embodiments of the application and in the drawings described above, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "may include" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solutions of the embodiments of the present application, and are not limited thereto. Although the embodiments of the present application have been described in detail with reference to the foregoing embodiments, those skilled in the art will understand that: it is also possible to modify the solutions described in the previous embodiments or to substitute some or all of them with equivalents. And the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present application.

Claims (8)

1. The utility model provides a LET network signal sharing transmitter shell corrects tool which characterized in that: including workstation, frame and at least 2 groups correction module, correct the module and install in the frame, the rack-mount is on the workstation, correct the module including correction cylinder, lifter plate, guide pillar subassembly and correction drift subassembly, correct the drift subassembly and install on the lifter plate, the lifter plate passes through the guide pillar subassembly and installs in the frame, correct the cylinder and can drive the lifter plate and move the correction drift subassembly and do elevating movement.

2. The LET network signal sharing transmitter housing calibration jig of claim 1, wherein: the correction module is including proofreading and correct drive block, first correction slider and second correction slider, the both sides of proofreading and correct the drive block are provided with first inclined plane and second inclined plane respectively, first correction slider passes through first reset spring unit mount on first inclined plane, and can follow first inclined plane and be elevating movement, second correction slider passes through second reset spring unit mount on the second inclined plane, and can follow the second inclined plane and be elevating movement.

3. The LET network signal sharing transmitter housing calibration jig of claim 2, wherein: the first correcting slide block is provided with a third inclined surface corresponding to the first inclined surface, and when the first correcting slide block moves upwards along the first inclined surface through the third inclined surface, the first correcting slide block moves away from the correcting driving block.

4. The LET network signal sharing transmitter housing calibration jig of claim 2, wherein: and when the second correcting slide block moves upwards along the first inclined plane through the fourth inclined plane, the second correcting slide block moves away from the correcting driving block.

5. The LET network signal sharing transmitter housing calibration jig of claim 2, wherein: the correcting module further comprises a resetting device for resetting the first correcting slide block and the second slide block.

6. The LET network signal sharing transmitter housing calibration jig of claim 5, wherein: the resetting device comprises a limiting strip, a first resetting spring, a second resetting spring, a first mounting block and a second mounting block, wherein a first limiting through groove is formed in the transverse direction of the first correcting slider, a second limiting through groove is formed in the transverse direction of the second correcting slider, the limiting strip is transversely mounted on the correcting driving block, one end of the limiting strip is inserted into the first limiting through groove, the other end of the limiting strip is inserted into the second limiting through groove, a first circular hole is vertically formed in the first limiting through groove in a downward penetrating mode through the first correcting slider, the first resetting spring penetrates through the first circular hole, the upper end of the first resetting spring is abutted against the bottom of the limiting strip, the lower end of the first resetting spring is abutted against the upper surface of the first mounting block, the first mounting block is mounted at the bottom of the first correcting slider, a second circular hole is formed in the second limiting through groove in a downward penetrating mode through the second correcting slider, the second resetting spring penetrates through the second circular hole, the upper end of the second resetting spring is abutted against the bottom of the limiting strip, the lower end of the second resetting spring is abutted against the second mounting block, the upper surface of the second correcting slider is mounted at the upper surface of the second correcting slider.

7. The LET network signal sharing transmitter housing calibration jig of claim 6, wherein: a first avoidance groove is formed in the outer side face of the second correcting sliding block, and a second avoidance groove is formed in the outer side face of the second mounting block.

8. The LET network signal sharing transmitter housing calibration jig of claim 1, wherein: the workbench is provided with a positioning block corresponding to the correction die set, and the positioning block is used for positioning the shell.

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