5G mobile communication signal all-round test equipment
Technical Field
The invention belongs to the field of 5G mobile communication signal equipment, and particularly relates to 5G mobile communication signal omnibearing testing equipment.
Background
The 5G is a fifth generation mobile phone system, which is an advanced development of the current 4G mobile communication technology, the current 5G communication signal equipment is still in the process of construction, after the construction of the 5G communication signal equipment is completed, the 5G communication signal in the current area needs to be tested, so that the current signal condition can be known, and then debugging is performed according to the condition, so that the 5G mobile communication signal omnibearing test equipment needs to be used when the 5G communication signal is tested, but the prior art has the following defects:
because when testing 5G mobile communication signal, need promote equipment to higher position and test to the cross section of equipment is great, when great in the wind, will blow equipment and rock, leads to the unstability of equipment during the test, thereby influences 5G mobile communication signal test's stability, makes the data tested have the error.
Therefore, the application provides the 5G mobile communication signal omnibearing test equipment which improves the defects.
Disclosure of Invention
Aiming at the defects in the prior art, the invention aims to provide 5G mobile communication signal omnibearing test equipment, which solves the problems that in the prior art, when a 5G mobile communication signal is tested, the equipment needs to be lifted to a higher position for testing, the cross section of the equipment is large, and when the wind is large, the equipment is blown to shake, so that the equipment is unstable during testing, the stability of the 5G mobile communication signal testing is influenced, and the tested data has errors.
In order to achieve the purpose, the invention is realized by the following technical scheme: the structure of the omnibearing test equipment for the mobile communication signals comprises a base, a fixed frame, a lifting frame, a main rod, an omnibearing test structure and a lightning rod, wherein the fixed frame is vertically arranged at the upper end of the base and is in mechanical connection; all-round test structure includes support, horizontal test structure, mounting disc structure, vertical test structure, link, the perpendicular embedding of support is installed in mounting disc structure lower extreme, the support outside is located and adopt mechanical connection to horizontal test structure cover, the link embedding is installed in mounting disc structure upper end inboard, vertical test structure mechanical connection is in the link upper end.
The invention is further improved, the transverse test structure comprises a mounting frame, an air hole, a buffer structure, arc edges and a signal detection module, the air hole penetrates through the inner side of the mounting frame, the buffer structure is embedded and mounted on the inner side of the mounting frame, the arc edges are arranged at the upper end and the lower end of the mounting frame and are of an integrated structure, and the signal detection module is embedded and mounted on the inner side of the mounting frame and is mechanically connected.
The invention is further improved, the buffer structure comprises a mounting groove, a connecting rod, a sliding block, an outer frame and a spring, the mounting groove penetrates through the left end of the connecting rod, the right end of the connecting rod is connected with the left end of the sliding block, the connecting rod penetrates through the inner side of the outer frame, the spring is embedded and mounted on the inner side of the outer frame, and the left end of the spring abuts against the right end of the sliding block.
The invention is further improved, the mounting disc structure comprises a mounting disc, an embedded groove, a sliding groove and a regulating block, the embedded groove is arranged on the inner side of the mounting disc and is of an integrated structure, the sliding groove is embedded and mounted on the inner side of the mounting disc, and the upper end of the regulating block is embedded in the inner side of the sliding groove and is movably connected.
The invention is further improved, the longitudinal test structure comprises a longitudinal mounting frame, longitudinal wind holes, wind plates, cambered surfaces and a self-adaptive structure, the longitudinal wind holes penetrate through the longitudinal mounting frame, the wind plates are arranged on two sides of the longitudinal mounting frame, the cambered surfaces are arranged on the inner sides of the wind plates and are of an integrated structure with the longitudinal mounting frame, and the self-adaptive structure is arranged on the left side of the longitudinal mounting frame and is horizontally arranged at the upper right end of the connecting frame.
The invention is further improved, the self-adaptive structure comprises a movable block, an adjusting plate, an arc groove and a curved spring, the arc groove is arranged on the inner side of the movable block and is of an integrated structure, and the adjusting plate is embedded and installed on the inner side of the arc groove and is arranged between the curved springs.
According to the technical scheme, the omnibearing test equipment for the 5G mobile communication signals has the following beneficial effects:
the invention respectively arranges a transverse test structure and a longitudinal test structure at the upper side and the lower side of a mounting disc structure, wind blows on the surface of a mounting frame, at the moment, the wind flows downwards along the inclination of the mounting frame, partial wind reduces the force caused by the wind through a wind hole, a small amount of wind blows the mounting frame to drive a buffer structure, at the moment, because the mounting groove of a connecting rod is fixed with a bracket, an outer frame and a sliding block move relatively, a spring at the inner side is compressed to buffer, the redundant force is transmitted to the bracket, at the moment, an adjusting block is driven to move relatively and buffer at the inner side of a sliding groove, wind at the upper end is blown at the right end of the longitudinal mounting frame, due to the action of a cambered surface, the wind flows to the upper side and the lower side, wind plates at the two sides bring force according to the blowing direction of the wind to drive a self-adaptive structure, an adjusting plate at the upper end of the moving block compresses or stretches a curved spring at the inner side of the cambered groove, the whole contact with wind of vertical test structure is adjusted to minimum area of contact, reduces the power from wind, has reduced because the rocking that blows of wind brought, and the stability of equipment during the increase test makes 5G mobile communication signal test's stability stronger, has improved the accuracy of testing out the data.
Drawings
Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:
FIG. 1 is a schematic structural diagram of a 5G mobile communication signal omni-directional testing apparatus according to the present invention;
FIG. 2 is a schematic structural diagram of an omni-directional test structure according to the present invention;
FIG. 3 is a schematic diagram of a front view of a lateral test structure according to the present invention;
FIG. 4 is a schematic side view of a lateral test structure according to the present invention;
FIG. 5 is a schematic structural diagram of a buffer structure according to the present invention;
FIG. 6 is a schematic top view of the mounting plate structure of the present invention;
FIG. 7 is a schematic front view of the mounting plate structure of the present invention;
FIG. 8 is a schematic structural view of a longitudinal test structure according to the present invention;
FIG. 9 is a schematic diagram of a front view of an adaptive architecture according to the present invention;
fig. 10 is a schematic top view of the adaptive structure of the present invention.
In the figure: the device comprises a base-1, a fixed frame-2, a lifting frame-3, a main rod-4, an omnibearing test structure-5, a lightning rod-6, a support-51, a transverse test structure-52, an installation disc structure-53, a longitudinal test structure-54, a connecting frame-55, an installation frame-521, an air hole-522, a buffer structure-523, an arc edge-524, a signal detection module-525, an installation groove-23 a, a connecting rod-23 b, a sliding block-23 c, an outer frame-23 d, a spring-23 e, an installation disc-531, an embedded groove-532, a sliding groove-533, a regulating block-534, a longitudinal installation frame-541, a longitudinal air hole-542, an air plate-543, an arc surface-544, a self-adaptive structure-545, a movable block-45 a, An adjusting plate-45 b, an arc groove-45 c and a curved spring-45 d.
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.
Referring to fig. 1-10, the embodiments of the present invention are as follows:
the structure of the device comprises a base 1, a fixed frame 2, a lifting frame 3, a main rod 4, an omnibearing test structure 5 and a lightning rod 6, wherein the fixed frame 2 is vertically arranged at the upper end of the base 1 and is in mechanical connection, the lifting frame 3 is arranged at the inner side of the fixed frame 2 and is in movable connection, the main rod 4 is embedded in the inner side of the lifting frame 3 and is in movable connection, the omnibearing test structure 5 is horizontally arranged at the upper end of the main rod 4 and is in mechanical connection, and the lightning rod 6 is vertically arranged at the upper end of the omnibearing test structure 5 and is positioned on the same axis; all-round test structure 5 includes support 51, horizontal test structure 52, mounting disc structure 53, vertical test structure 54, link 55, support 51 perpendicular embedding is installed in mounting disc structure 53 lower extreme, the support 51 outside is located and adopt mechanical connection to horizontal test structure 52 cover, link 55 embedding is installed in mounting disc structure 53 upper end inboard, vertical test structure 54 mechanical connection is in link 55 upper end.
Referring to fig. 3-4, the transverse test structure 52 includes an installation frame 521, an air hole 522, a buffering structure 523, an arc edge 524 and a signal detection module 525, the air hole 522 penetrates through the inside of the installation frame 521, the buffering structure 523 is embedded in the inside of the installation frame 521, the arc edge 524 is arranged at the upper end and the lower end of the installation frame 521 and is of an integrated structure, the signal detection module 525 is embedded in the inside of the installation frame 521 and is mechanically connected, the installation frame 521 inclines upwards, the circulation of air is facilitated, the air hole 522 facilitates the passage of air, the force caused by the air is reduced, and the buffering structure 523 buffers the air.
Referring to fig. 5, the buffering structure 523 includes an installation groove 23a, a connection rod 23b, a slider 23c, an outer frame 23d, and a spring 23e, where the installation groove 23a penetrates through the left end of the connection rod 23b, the right end of the connection rod 23b is connected to the left end of the slider 23c, the connection rod 23b penetrates through the inner side of the outer frame 23d, the spring 23e is embedded in the inner side of the outer frame 23d, and the left end of the spring is abutted against the right end of the slider 23c, and when the force of wind pushes the slider 23c inside the connection rod 23b to squeeze the spring 23e, the force of wind is buffered.
Referring to fig. 6-7, the mounting plate structure 53 includes a mounting plate 531, an embedded groove 532, a sliding groove 533, and an adjusting block 534, the embedded groove 532 is disposed inside the mounting plate 531 and is an integrated structure, the sliding groove 533 is embedded inside the mounting plate 531, and an upper end of the adjusting block 534 is embedded inside the sliding groove 533 and is movably connected to the sliding groove 533, so that the wind power brought by the transverse testing structure 52 can be buffered in a left-right movement.
Referring to fig. 8, the longitudinal test structure 54 includes a longitudinal mounting frame 541, a longitudinal air hole 542, air plates 543, an arc surface 544, and an adaptive structure 545, wherein the longitudinal air hole 542 penetrates through the longitudinal mounting frame 541, the air plates 543 are disposed at two sides of the longitudinal mounting frame 541, the arc surface 544 is disposed at an inner side of the air plates 543 and is integrated with the longitudinal mounting frame 541, the adaptive structure 545 is mounted at a left side of the longitudinal mounting frame 541 and is horizontally mounted at a right upper end of the connecting frame 55, wind flows out from upper and lower ends according to the arc surface 544, and the air plates 543 at two sides can change positions of the adaptive structure 545 according to a wind direction, so as to reduce a contact area with the wind and reduce a force of the wind.
Referring to fig. 9-10, the adaptive structure 545 includes a movable block 45a, an adjusting plate 45b, an arc groove 45c, and a curved spring 45d, wherein the arc groove 45c is disposed inside the movable block 45a and is an integrated structure, the adjusting plate 45b is inserted into and mounted inside the arc groove 45c and disposed between the curved springs 45d, and the adjusting plate 45b is adjusted by changing the wind direction, so that the curved spring 45d is compressed and stretched in the arc groove 45c for adjustment.
Based on the above embodiment, the specific working principle is as follows:
firstly, the base 1 is installed on a test vehicle convenient to move, the lifting frame 3 is lifted to push the main rod 4 to the highest position, namely, the signal detection module 525 can be utilized to start the test of 5G mobile communication signals, when the wind is strong, the wind blows on the surface of the installation frame 521, at the moment, the wind flows downwards along the inclination of the installation frame, part of the wind reduces the force caused by the wind through the wind hole 522, a small amount of the wind blows the installation frame 521 to drive the buffer structure 523, at the moment, because the installation groove 23a of the connecting rod 23b is fixed with the bracket 51, the outer frame 23d moves relative to the sliding block 23c, the inner spring 23e is compressed to buffer, the redundant force is transmitted to the bracket 51, at the moment, the adjusting block 534 is driven to perform relative movable buffer on the inner side of the sliding groove 533, the wind at the upper end is blown to the right end of the longitudinal direction 541, and due to the installation frame of the cambered, the wind plates 543 on both sides bring force according to the blowing direction of the wind to drive the adaptive structure 545, the adjusting plate 45b at the upper end of the movable block 45a compresses or stretches the curved spring 45d inside the arc groove 45c, so that the contact between the whole longitudinal test structure 54 and the wind is adjusted to the minimum contact area, and the force from the wind is reduced.
The invention solves the problems that in the prior art, when 5G mobile communication signals are tested, equipment needs to be lifted to a higher position for testing, the cross section of the equipment is larger, when the equipment is larger in wind, the equipment is blown to shake, so that the equipment is unstable during testing, the stability of the 5G mobile communication signal testing is influenced, and the tested data has errors, through the mutual combination of the components, the transverse testing structure and the longitudinal testing structure are respectively arranged at the upper side and the lower side of the mounting plate structure, wind blows on the surface of the mounting frame, at the moment, the wind flows downwards along the inclination of the mounting frame, part of the wind reduces the force caused by the wind through the wind holes, and a small amount of the wind blows on the mounting frame to drive the buffer structure, at the moment, because the mounting groove of the connecting rod is fixed with the bracket, the outer frame moves relative to the sliding block, and the spring at the inner side is compressed for buffering, and unnecessary power will pass to on the support, will drive the regulating block and carry out relative activity buffering in the spout inboard this moment, and the wind of upper end will blow at vertical mounting bracket right-hand member, because the effect of cambered surface, wind will flow to upper and lower both sides, and the aerofoil of both sides will bring the power according to the blowing direction of wind, and drive adaptive structure, the regulating plate of movable block upper end will compress or stretch the curved spring of arc inslot inboard, will make vertical test structure whole and the contact regulation of wind to minimum area of contact, reduce the power that comes from the wind, the rocking of bringing because the blowing of wind has been reduced, the stability of equipment when increasing the test, make the stability of 5G mobile communication signal test stronger, the accuracy of the test data has been improved.
While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.
Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.