CN112180130A - 5G signal test probe - Google Patents

Abstract

The invention relates to the technical field of 5G, in particular to a 5G signal test probe, which comprises a double-shaft motor, a screw rod, a lifting lower plate, a U-shaped plate, a rotating block, a rotating motor and a test probe, wherein the screw rod is fixedly connected to the upper part of the double-shaft motor, the lifting lower plate is in threaded transmission connection with the screw rod, the lifting lower plate can rotate on the screw rod, the U-shaped plate is fixedly connected to the lifting lower plate, the rotating block is rotatably connected into the U-shaped plate through a pin shaft, an output shaft of the rotating motor is fixedly connected with the rotating block, and the upper part of the rotating motor is fixedly connected with the plurality of test probes.

Description

5G signal test probe

Technical Field

The invention relates to the technical field of 5G, in particular to a 5G signal test probe.

Background

Compared with a 4G network, the 5G network communication technology which is the most advanced network communication technology at present has obvious advantages, not only is the transmission speed relatively high, but also has strong compatibility, the service life of a battery is obviously prolonged, the life of people is more convenient, a plurality of countries in the world enter the research work of the 5G network communication technology at present, and the transmission speed is greatly improved in the future along with the continuous and deep research on the problem.

The invention has the function of simulating and measuring various scene signals.

Disclosure of Invention

The invention provides a 5G signal test probe, which has the beneficial effect that the probe has the function of simulating and measuring various scene signals.

The invention relates to the technical field of 5G, in particular to a 5G signal test probe, which comprises a double-shaft motor, a screw rod, a lifting lower plate, a U-shaped plate, a rotating block, a rotating motor and a test probe.

The upper portion fixedly connected with lead screw of biax motor, the lift hypoplastron passes through screw thread transmission with the lead screw to be connected, and the lift hypoplastron can rotate on the lead screw, and U template fixed connection is on the lift hypoplastron, and the turning block rotates through the round pin axle to be connected in the U template, rotates the output shaft and the turning block fixed connection of motor, rotates a plurality of test probes of the upper portion fixedly connected with of motor.

The utility model provides a 5G signal test probe still includes the leveling board, the screw ring, the leveling post, spout I, spout II and spacing seat, the equal fixedly connected with screw ring in four angle departments of leveling board, the equal threaded connection in every screw ring has the leveling post, it is fixed with the leveling post with the screw ring through the screw that screws, the upper portion of leveling board is provided with two spout I, the middle part of leveling board upside is provided with spout II, the front end fixedly connected with mounting panel of spout II, the spacing seat of upper portion fixedly connected with of leveling board, be provided with two spacing grooves on the spacing seat.

The 5G signal test probe further comprises a placing frame and a sliding column, the placing frame is fixedly connected to the leveling plate, the sliding column is fixedly connected to the right side of the upper portion of the placing frame, the double-shaft motor is fixedly connected to the lower portion of the placing frame, and the lead screw penetrates through the placing frame.

The utility model provides a 5G signal test probe still includes the lift upper plate, electric putter, spacing piece I, circular arc groove I and circular arc groove II, the lift upper plate passes through screw drive with the lead screw and is connected, two electric putter of the upper portion fixedly connected with of lift hypoplastron, two spacing pieces I of equal fixedly connected with are served in two electric putter's activity, a plurality of spacing pieces I are located the upper and lower both sides of lift upper plate respectively, the middle part of lift upper plate upside is provided with two circular arc grooves II, the left end of lift upper plate upside is provided with circular arc groove II, electric putter's expansion end sliding connection is in circular arc groove I.

The 5G signal test probe further comprises a rectangular sliding column, a sliding block, a limiting piece II and a protective cover, wherein the rectangular sliding column is fixedly connected to the upper portion of the left side and the upper portion of the right side of the U-shaped plate, the limiting piece II is fixedly connected to the upper end and the lower end of the sliding block, the protective cover is fixedly connected to the lower portion of the lower limiting piece II, the lifting upper plate is located between the two limiting pieces II, the two rectangular sliding columns are connected with the two limiting pieces II in a sliding mode, and the sliding block is connected in the arc groove II in a sliding mode.

The 5G signal test probe further comprises an I-shaped rotating shaft, locking claws, a clasping ring I, a clasping ring II and a T-shaped rotating column, the locking claws are connected to the I-shaped rotating shaft in a rotating mode, the left ends of the locking claws are fixedly connected with the clasping ring I, the right ends of the locking claws are fixedly connected with the clasping ring II, the T-shaped rotating column is fixedly connected to the middle of the upper side of each locking claw, the two locking claws are arranged symmetrically, the I-shaped rotating shaft is connected to the lifting lower plate in a rotating mode, a lead screw is matched with the two clasping rings I, and a sliding column is matched with the two clasping rings II.

The utility model provides a 5G signal test probe still includes the turning block, two-way lead screw I, gear II, adjustment motor and jam plate, all rotate on two T type rotary columns and be connected with the turning block, two turning blocks are threaded connection respectively at the both ends of two-way lead screw I, the middle part fixedly connected with gear I of two-way lead screw I, gear I is connected with II meshing transmissions of gear, II fixed connection of gear are on adjustment motor's output shaft, fixedly connected with jam plate on the adjustment motor, the jam plate rotates with two-way lead screw I to be connected, the equal sliding connection of two T type rotary columns is in the spout III on the hypoplastron that goes up and down, the lower part sliding connection of adjustment motor is in the spout IV on the hypop.

The utility model provides a 5G signal test probe still includes bevel gear I, two-way lead screw II, bevel gear II, the spacing ring, slide and fixed bearing frame, I fixed connection of bevel gear is on the output shaft of double-shaft motor lower extreme, bevel gear I is connected with II meshing transmissions of bevel gear, II fixed connection of bevel gear are at the middle part of two-way lead screw II, the equal fixedly connected with spacing ring in both sides at two-way lead screw II middle parts, there is the slide both ends of two-way lead screw II all through threaded connection, the both ends of two-way lead screw II rotate respectively to be connected in two fixed.

The 5G signal testing probe further comprises an I-shaped sliding block and two ground grabbing claws, wherein the I-shaped sliding block is connected with the sliding groove I in a sliding mode, the lower portion of each I-shaped sliding block is fixedly connected with the ground grabbing claws, the I-shaped sliding blocks are attached to the sliding plate, and the number of the I-shaped sliding blocks is two.

The 5G signal test probe further comprises a sliding seat, limiting plates and a rotating shaft, wherein the two limiting plates are fixedly connected to the upper portion of the sliding seat, the rotating shaft is rotatably connected with the two limiting plates, a limiting rod is fixedly connected to the tail end of the rotating shaft, the limiting rod is matched with the two limiting grooves in the limiting seat, and the two limiting plates are matched with the two limiting rings respectively.

The 5G signal test probe has the beneficial effects that:

the leveling plate is placed in the area where the test signal is needed, then a plurality of leveling columns are adjusted to keep the leveling plate horizontal, due to the adjustable function of the leveling columns, the device can adapt to various outdoor terrains, the measuring area range of the device is enlarged, the plurality of leveling columns are fixed by locking the screws on the plurality of threaded rings, thereby the leveling plate can be kept horizontal, the rotating motor is started, the rotating motor output shaft drives the rotating block to rotate by taking the axis of the rotating motor output shaft as a shaft, a plurality of test probes can simulate a dynamic signal measurement scene, thereby increasing the measuring range, simultaneously measuring by a plurality of test probes, improving the measuring precision, covering the plurality of test probes by the protective cover, therefore, the protection function is achieved, and furthermore, the lifting upper plate can enable the lifting lower plate to rotate more stably by taking the axis of the lead screw as a shaft.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic diagram of an overall structure of a 5G signal test probe according to the present invention;

FIG. 2 is a schematic diagram of an overall structure of a 5G signal test probe according to the present invention;

FIG. 3 is a schematic diagram of a partial structure of a 5G signal test probe according to the present invention;

FIG. 4 is a schematic view of the structure of the lifting lower plate;

FIG. 5 is a schematic view of a part of the structure of the lifting lower plate and the U-shaped plate;

FIG. 6 is a schematic structural view of the drum-shaped shaft;

FIG. 7 is a schematic structural diagram of a bidirectional screw II;

FIG. 8 is a schematic view of the structure of the drum block;

fig. 9 is a schematic structural diagram of the slider.

In the figure: a leveling plate 1; 1-1 of a threaded ring; leveling columns 1-2; 1-3 of a chute; a chute II 1-4; 1-5 parts of a limiting seat; placing racks 1-6; 1-7 of a sliding column; a double-shaft motor 2; 2-1 of a screw rod; bevel gears 2-2; lifting the lower plate 3; lifting the upper plate 3-1; an electric push rod 3-2; 3-3 parts of a limiting piece; 3-4 of arc groove; 3-5 of arc groove II; a U-shaped plate 4; 4-1 of a rotating block; rotating the motor 4-2; 4-3 of a test probe; 4-4 of a rectangular sliding column; 4-5 of a sliding block; 4-6 of a limiting sheet; 4-7 of a protective cover; an i-shaped rotating shaft 5; 5-1 of a locking claw; 5-2 of a holding ring; 5-3 of a holding ring; 5-4 of T-shaped rotating columns; 5-5 of a rotating block; 5-6 parts of a bidirectional screw; 5-7 parts of a gear I; 5-8 parts of a gear II; adjusting a motor 5-9; 5-10 parts of a locking plate; a bidirectional screw II 6; a bevel gear II 6-1; 6-2 of a limiting ring; 6-3 of a sliding plate; a bearing seat 6-4 is fixed; an I-shaped slide block 7; a ground gripping claw 7-1; a slide 8; a limiting plate 8-1; a rotating shaft 8-2.

Detailed Description

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing and simplifying the description, but do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore are not to be construed as limiting the invention, and further, the terms "first", "second", etc., are used only for descriptive purposes and are not intended to indicate or imply relative importance or to implicitly indicate the number of technical features indicated, whereby the features defined as "first", "second", etc., may explicitly or implicitly include one or more of such features, in the description of the present invention, "a plurality" means two or more unless otherwise specified.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 9, and the invention relates to the technical field of 5G, in particular to a 5G signal test probe, which comprises a double-shaft motor 2, a lead screw 2-1, a lifting lower plate 3, a U-shaped plate 4, a rotating block 4-1, a rotating motor 4-2 and a test probe 4-3.

The upper part of the double-shaft motor 2 is fixedly connected with a screw 2-1, the lifting lower plate 3 is connected with the screw 2-1 through thread transmission, the lifting lower plate 3 can rotate on the screw 2-1, the U-shaped plate 4 is fixedly connected on the lifting lower plate 3, the rotating block 4-1 is rotatably connected in the U-shaped plate 4 through a pin shaft, the output shaft of the rotating motor 4-2 is fixedly connected with the rotating block 4-1, the upper part of the rotating motor 4-2 is fixedly connected with a plurality of test probes 4-3, the screw 2-1 can drive the lifting lower plate 3 to rotate by taking the axis of the screw 2-1 as the shaft through the double-shaft motor 2, the rotating motor 4-2 can drive the rotating block 4-1 to rotate by taking the axis of the output shaft of the rotating motor 4-2 as the shaft, and the plurality of test probes 4-3 can simulate a dynamic signal measurement scene, therefore, the measurement range is enlarged, and the plurality of test probes 4-3 can simultaneously perform measurement, so that the measurement precision can be improved.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-9, the 5G signal testing probe further comprises a leveling plate 1, a threaded ring 1-1, leveling columns 1-2, sliding grooves i 1-3, sliding grooves ii 1-4 and limiting seats 1-5, the threaded rings 1-1 are fixedly connected at four corners of the leveling plate 1, the leveling columns 1-2 are connected in each threaded ring 1-1 in a threaded manner, the threaded rings 1-1 and the leveling columns 1-2 are fixed by screwing screws, the upper portion of the leveling plate 1 is provided with the two sliding grooves i 1-3, the middle portion of the upper side of the leveling plate 1 is provided with the sliding grooves ii 1-4, the front ends of the sliding grooves ii 1-4 are fixedly connected with a mounting plate, the upper portion of the leveling plate 1 is fixedly connected with the limiting seats 1-5, and the limiting seats 1-5 are provided with the two limiting grooves, due to the adjustable function of the leveling columns 1-2, the device can adapt to various outdoor terrains, the measuring area range of the device is expanded, and the leveling columns 1-2 are fixed by locking the screws on the threaded rings 1-1, so that the leveling plate 1 can be kept horizontal.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 9, the 5G signal testing probe further includes a placing rack 1 to 6 and a sliding column 1 to 7, the placing rack 1 to 6 is fixedly connected to the leveling plate 1, the sliding column 1 to 7 is fixedly connected to the right side of the upper portion of the placing rack 1 to 6, the double-shaft motor 2 is fixedly connected to the lower portion of the placing rack 1 to 6, the screw rod 2 to 1 penetrates through the placing rack 1 to 6, and the screw rod 2 to 1 can drive the lifting lower plate 3 to achieve the lifting function through the sliding column 1 to 7.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1-9, the 5G signal testing probe further includes a lifting upper plate 3-1, an electric push rod 3-2, a limiting piece i 3-3, an arc groove i 3-4 and an arc groove ii 3-5, the lifting upper plate 3-1 is connected with a screw 2-1 through screw transmission, two electric push rods 3-2 are fixedly connected to the upper portion of the lifting lower plate 3, two limiting pieces i 3-3 are fixedly connected to the movable ends of the two electric push rods 3-2, the limiting pieces i 3-3 are respectively located at the upper and lower sides of the lifting upper plate 3-1, two arc grooves ii 3-5 are arranged in the middle of the upper side of the lifting upper plate 3-1, the arc groove ii 3-5 is arranged at the left end of the upper side of the lifting upper plate 3-1, the movable end of the electric push rod 3-2 is slidably connected in the arc groove i 3-4, the lifting upper plate 3-1 can enable the lifting lower plate 3 to rotate more stably by taking the axis of the lead screw 2-1 as an axis.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1-9, the 5G signal testing probe further includes a rectangular sliding column 4-4, a sliding block 4-5, a limiting piece ii 4-6 and a protective cover 4-7, the upper portions of the left and right sides of the U-shaped plate 4 are fixedly connected with the rectangular sliding column 4-4, the upper and lower ends of the sliding block 4-5 are fixedly connected with the limiting piece ii 4-6, the lower portion of the lower limiting piece ii 4-6 is fixedly connected with the protective cover 4-7, the lifting upper plate 3-1 is positioned between the two limiting pieces ii 4-6, the two rectangular sliding columns 4-4 are slidably connected with the two limiting pieces ii 4-6, the sliding block 4-5 is slidably connected in the arc groove ii 3-5, and the protective cover 4-7 is provided to avoid damage to the plurality of testing probes 4-3 caused by high-speed rotation, the protective cover 4-7 can protect a plurality of test probes 4-3, the two electric push rods 3-2 are started to drive the arc grooves I3-4 to descend, the lifting upper plate 3-1 rotates by taking the axis of the screw rod 2-1 as the shaft in the descending process of the lifting upper plate 3-1 as the lifting upper plate 3-1 is in threaded connection with the screw rod 2-1, the movable ends of the two electric push rods 3-2 slide in the two arc grooves I3-4 respectively at the moment, the sliding block 4-5 slides in the arc grooves II 3-5 at the moment, and the vertical positions of the protective cover 4-7 and the plurality of test probes 4-3 are relatively fixed by sliding the two rectangular sliding columns 4-4 on the two limiting pieces II 4-6, when the lifting upper plate 3-1 descends, the protective cover 4-7 covers the plurality of test probes 4-3, so that the protective function is achieved.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1-9, the 5G signal testing probe further includes an i-shaped rotating shaft 5, a locking claw 5-1, a clasping ring i 5-2, a clasping ring ii 5-3 and a T-shaped rotating column 5-4, the i-shaped rotating shaft 5 is rotatably connected with the locking claw 5-1, the left end of the locking claw 5-1 is fixedly connected with the clasping ring i 5-2, the right end of the locking claw 5-1 is fixedly connected with the clasping ring ii 5-3, the middle part of the upper side of the locking claw 5-1 is fixedly connected with the T-shaped rotating column 5-4, the two locking claws 5-1 are arranged in central symmetry, the i-shaped rotating shaft 5 is rotatably connected to the lifting lower plate 3, the screw 2-1 is matched with the two clasping rings i 5-2, the slide columns 1-7 are matched with the two clasping rings, when the two clasping rings II 5-3 are close to each other to lock the sliding columns 1-7, the lifting function of lifting the lower plate 3 can be realized, and when the two clasping rings I5-2 are close to each other to lock the screw rod 2-1, the self-rotating function of lifting the lower plate 3 can be realized.

The seventh embodiment:

the embodiment is described below with reference to fig. 1 to 9, the 5G signal testing probe further includes rotation blocks 5 to 5, a bidirectional screw i 5 to 6, gears i 5 to 7, gears ii 5 to 8, an adjusting motor 5 to 9 and lock plates 5 to 10, the rotation blocks 5 to 5 are rotatably connected to two T-shaped rotation columns 5 to 4, the two rotation blocks 5 to 5 are respectively and threadedly connected to two ends of the bidirectional screw i 5 to 6, the gears i 5 to 7 are fixedly connected to the middle portion of the bidirectional screw i 5 to 6, the gears i 5 to 7 are in meshing transmission connection with the gears ii 5 to 8, the gears ii 5 to 8 are fixedly connected to output shafts of the adjusting motor 5 to 9, the lock plates 5 to 10 are fixedly connected to the adjusting motor 5 to 9, the lock plates 5 to 10 are rotatably connected to the bidirectional screw i 5 to 6, two T-shaped rotating columns 5-4 are both connected in a sliding groove III on a lifting lower plate 3 in a sliding way, the lower part of an adjusting motor 5-9 is connected in a sliding groove IV on the lifting lower plate 3 in a sliding way, the output shaft of the adjusting motor 5-9 can drive a gear II 5-8 to rotate by taking the self axis as the shaft by starting the adjusting motor 5-9, the adjusting motor 5-9 is driven by the gear II 5-8 to rotate, the two T-shaped rotating columns 5-4 are far away from or close to each other, at the moment, the two T-shaped rotating columns 5-4 slide in a sliding groove III on the lifting lower plate 3, the lower part of the adjusting motor 5-9 slides left and right in the sliding groove IV on the lifting lower plate 3, when the two clasping rings II 5-3 are close to each other to lock the sliding columns 1-7, the lifting function of the lifting lower plate 3 can be, the output shaft of the double-shaft motor 2 drives the screw rod 2-1 to rotate by taking the axis of the screw rod 2-1 as the shaft, so that the lifting of the lifting lower plate 3 is realized, the plurality of test probes 4-3 are driven to lift, the plurality of test probes 4-3 are measured at different positions in the vertical direction, the measurement range is further increased, after the lifting lower plate 3 is lifted to a proper height, the adjusting motor 5-9 is started, the output shaft of the adjusting motor 5-9 drives the gear II 5-8 to rotate by taking the axis of the screw rod as the shaft, the gear I5-7 is driven to rotate by the gear II 5-8, the two clasping rings I5-2 are close to each other to lock the screw rod 2-1, the self-rotating function of the lifting lower plate 3 is realized, at the moment, the rotation of the screw rod 2-1 drives the lifting lower plate 3 to rotate by taking, therefore, the plurality of test probes 4-3 can simulate a dynamic signal measurement scene, and the measurement effect is further improved.

The specific implementation mode is eight:

the embodiment is described below with reference to fig. 1-9, the 5G signal testing probe further includes a bevel gear i 2-2, a bidirectional screw ii 6, a bevel gear ii 6-1, a limiting ring 6-2, a sliding plate 6-3 and a fixed bearing seat 6-4, the bevel gear i 2-2 is fixedly connected to an output shaft at the lower end of a biaxial motor 2, the bevel gear i 2-2 is in meshing transmission connection with the bevel gear ii 6-1, the bevel gear ii 6-1 is fixedly connected to the middle portion of the bidirectional screw ii 6, both sides of the middle portion of the bidirectional screw ii 6 are fixedly connected with the limiting ring 6-2, both ends of the bidirectional screw ii 6 are connected with the sliding plate 6-3 through threads, both ends of the bidirectional screw ii 6 are respectively rotatably connected in the two fixed bearing seats 6-4, when the bevel gear 2-2 is meshed with the bevel gear ii 6-, the bevel gear 2-2 drives the bevel gear II 6-1 to rotate by taking the axis of the bevel gear II as a shaft, so that the function that the two sliding plates 6-3 are close to or far away from each other is realized, and the device is conveniently fixed on the ground.

The specific implementation method nine:

the embodiment is described below with reference to fig. 1 to 9, the 5G signal testing probe further includes a i-shaped slider 7 and a ground-grasping claw 7-1, the i-shaped slider 7 is slidably connected to the sliding chute i 1-3, the ground-grasping claw 7-1 is fixedly connected to the lower portion of each i-shaped slider 7, the i-shaped slider 7 is attached to the sliding plate 6-3, and the i-shaped sliders 7 are provided in two numbers, so that the two ground-grasping claws 7-1 can achieve a ground-grasping function by the two i-shaped sliders 7 approaching to each other, and the device can be fixed on the ground.

The detailed implementation mode is ten:

referring to fig. 1-9, the present embodiment will be described, wherein the 5G signal testing probe further comprises a sliding base 8, two limiting plates 8-1 and a rotating shaft 8-2, the upper portion of the sliding base 8 is fixedly connected with the two limiting plates 8-1, the rotating shaft 8-2 is rotatably connected with the two limiting plates 8-1, the end of the rotating shaft 8-2 is fixedly connected with a limiting rod, the limiting rod is matched with the two limiting grooves on the limiting base 1-5, the two limiting plates 8-1 are respectively matched with the two limiting rings 6-2, the limiting plate 8-1 is dragged in the front-back direction of the sliding groove ii 1-4, the two limiting rings 6-2 are driven by the two limiting plates 8-1, so that the bevel gear 2-2 is engaged with or separated from the bevel gear ii 6-1, and the limiting rod on the rotating shaft 8-2, the fixing effect is realized.

The invention relates to a working principle of a 5G signal test probe, which comprises the following steps:

the leveling plate 1 is placed in an area needing to be tested for signals, then a plurality of leveling columns 1-2 are adjusted to enable the leveling plate 1 to be kept horizontal, due to the adjustable function of the leveling columns 1-2, the device can adapt to various outdoor terrains, the measuring area range of the device is expanded, the leveling columns 1-2 are fixed by locking screws on a plurality of threaded rings 1-1, so that the leveling plate 1 can be kept horizontal, a limiting plate 8-1 is dragged in the front-back direction of a sliding groove II 1-4, two limiting rings 6-2 are driven by the two limiting plates 8-1 to enable a bevel gear 2-2 to be meshed with or separated from a bevel gear II 6-1, a limiting rod on a rotating shaft 8-2 is matched with the two limiting grooves to achieve the fixing effect, the limiting plate 8-1 is pushed to enable the bevel gear 2-2 to be meshed with the bevel gear II 6-1, and the limiting rod is pressed in one of the two limiting grooves, at the moment, the double-shaft motor 2 is started, the output shaft of the double-shaft motor 2 drives the bevel gear 2-2 to rotate, the bevel gear 2-2 drives the bevel gear II 6-1 to rotate by taking the axis of the bevel gear as the shaft, the two sliding plates 6-3 are close to or far away from each other, so that the two I-shaped sliding blocks 7 are close to each other, the two ground gripping claws 7-1 realize the ground gripping function, the device can be fixed on the ground, then the limiting plate 8-1 is adjusted to enable the bevel gear 2-2 and the bevel gear II 6-1 to be far away from each other, the limiting rod is pressed in the other of the two limiting grooves, at the moment, the rotating motor 4-2 is started, the output shaft of the rotating motor 4-2 drives the rotating block 4-, the plurality of test probes 4-3 can simulate a dynamic signal measurement scene, so that the measurement range is enlarged, the plurality of test probes 4-3 can simultaneously measure, the measurement precision can be improved, the adjusting motor 5-9 can be started, the output shaft of the adjusting motor 5-9 can drive the gear II 5-8 to rotate by taking the axis of the adjusting motor 5-8 as the shaft, the adjusting motor 5-9 is driven by the gear II 5-8 to rotate, the two T-shaped rotating columns 5-4 are far away from or close to each other, at the moment, the two T-shaped rotating columns 5-4 slide in the chute III on the lifting lower plate 3, the lower part of the adjusting motor 5-9 slides left and right in the chute IV on the lifting lower plate 3, and when the two clasping rings II 5-3 are close to each other to lock the sliding columns 1-7, the lifting function of the lifting lower plate 3 can be realized, starting the double-shaft motor 2, enabling an output shaft of the double-shaft motor 2 to drive the screw rod 2-1 to rotate by taking the axis of the screw rod 2-1 as an axis, thereby realizing the lifting of the lifting lower plate 3, further driving the plurality of test probes 4-3 to lift, thereby enabling the plurality of test probes 4-3 to measure at different positions in the vertical direction, further increasing the measurement range, starting the adjusting motor 5-9 after the lifting lower plate 3 is lifted to a proper height, enabling an output shaft of the adjusting motor 5-9 to drive the gear II 5-8 to rotate by taking the axis of the gear II 5-8 as an axis, driving the gear I5-7 to rotate by the gear II 5-8, enabling the two clasping rings I5-2 to approach each other so as to lock the screw rod 2-1, thereby realizing the self-rotating function of the lifting lower plate 3, and due to the V-shaped, the sliding column 1-7 can not be impacted in the rotating process, at the moment, the rotating of the screw rod 2-1 drives the lifting lower plate 3 to rotate by taking the axis of the lifting lower plate as the shaft, so that the plurality of test probes 4-3 can simulate a dynamic signal measurement scene, the measurement effect is further improved, when the lifting lower plate 3 is used for measuring in a region with larger dust, in order to avoid the damage to the plurality of test probes 4-3 caused by high-speed rotation, the protective cover 4-7 is arranged, the protective cover 4-7 can protect the plurality of test probes 4-3, the two electric push rods 3-2 are started to drive the arc groove I3-4 to descend, the lifting upper plate 3-1 is connected with the screw rod 2-1 through threads, in the descending process of the lifting upper plate 3-1, the lifting upper plate 3-1 rotates by taking the axis of the screw rod 2-1 as the shaft, at the moment, the movable ends of the two electric push rods 3-2 respectively slide in the two arc grooves I3-4, the sliding blocks 4-5 slide in the arc grooves II 3-5, the vertical positions of the protective covers 4-7 and the plurality of test probes 4-3 are relatively fixed by sliding the two rectangular sliding columns 4-4 on the two limiting pieces II 4-6, and the protective covers 4-7 cover the plurality of test probes 4-3 in the descending process of the lifting upper plate 3-1, so that the protection function is achieved, and further, the lifting upper plate 3-1 can enable the lifting lower plate 3 to rotate more stably by taking the axis of the screw rod 2-1 as an axis.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (10)

1. The utility model provides a 5G signal test probe, includes biax motor (2), lead screw (2-1), goes up and down hypoplastron (3), U template (4), turning block (4-1), rotation motor (4-2) and test probe (4-3), its characterized in that: the upper portion of the double-shaft motor (2) is fixedly connected with a lead screw (2-1), a lifting lower plate (3) is connected with the lead screw (2-1) through thread transmission, the lifting lower plate (3) can rotate on the lead screw (2-1), a U-shaped plate (4) is fixedly connected onto the lifting lower plate (3), a rotating block (4-1) is rotatably connected into the U-shaped plate (4) through a pin shaft, an output shaft of the rotating motor (4-2) is fixedly connected with the rotating block (4-1), and a plurality of test probes (4-3) are fixedly connected to the upper portion of the rotating motor (4-2).

2. The 5G signal test probe of claim 1, wherein: the high polymer material mixing and extruding system further comprises a leveling plate (1), threaded rings (1-1), leveling columns (1-2), sliding grooves I (1-3), sliding grooves II (1-4) and limiting seats (1-5), the threaded rings (1-1) are fixedly connected at four corners of the leveling plate (1), the leveling columns (1-2) are connected in each threaded ring (1-1) in a threaded manner, the threaded rings (1-1) and the leveling columns (1-2) are fixed through screwing screws, the two sliding grooves I (1-3) are arranged at the upper part of the leveling plate (1), the sliding grooves II (1-4) are arranged at the middle part of the upper side of the leveling plate (1), the mounting plates are fixedly connected at the front ends of the sliding grooves II (1-4), the limiting seats (1-5) are fixedly connected at the upper part of the leveling plate (1), two limiting grooves are arranged on the limiting seats (1-5).

3. The 5G signal test probe of claim 2, wherein: the high polymer material mixing and extruding system further comprises a placing frame (1-6) and sliding columns (1-7), the placing frame (1-6) is fixedly connected to the leveling plate (1), the sliding columns (1-7) are fixedly connected to the right side of the upper portion of the placing frame (1-6), the double-shaft motor (2) is fixedly connected to the lower portion of the placing frame (1-6), and the lead screw (2-1) penetrates through the placing frame (1-6).

4. The 5G signal test probe of claim 3, wherein: the high polymer material mixing and extruding system further comprises a lifting upper plate (3-1), electric push rods (3-2), limiting pieces I (3-3), arc grooves I (3-4) and arc grooves II (3-5), wherein the lifting upper plate (3-1) is in threaded transmission connection with a screw rod (2-1), the upper part of the lifting lower plate (3) is fixedly connected with the two electric push rods (3-2), the movable ends of the two electric push rods (3-2) are fixedly connected with the two limiting pieces I (3-3), the limiting pieces I (3-3) are respectively positioned at the upper side and the lower side of the lifting upper plate (3-1), the middle part of the upper side of the lifting upper plate (3-1) is provided with the two arc grooves II (3-5), the left end of the upper side of the lifting upper plate (3-1) is provided with the arc grooves II (3-5), the movable end of the electric push rod (3-2) is connected in the arc groove I (3-4) in a sliding manner.

5. The 5G signal test probe of claim 4, wherein: the high polymer material mixing extrusion system further comprises rectangular sliding columns (4-4), sliding blocks (4-5), limiting pieces II (4-6) and protective covers (4-7), the upper portions of the left side and the right side of the U-shaped plate (4) are fixedly connected with the rectangular sliding columns (4-4), the upper ends and the lower ends of the sliding blocks (4-5) are fixedly connected with the limiting pieces II (4-6), the lower portions of the lower limiting pieces II (4-6) are fixedly connected with the protective covers (4-7), the lifting upper plate (3-1) is located between the two limiting pieces II (4-6), the two rectangular sliding columns (4-4) are connected with the two limiting pieces II (4-6) in a sliding mode, and the sliding blocks (4-5) are connected in the arc grooves II (3-5) in a sliding mode.

6. The 5G signal test probe of claim 5, wherein: the high polymer material mixing extrusion system further comprises an I-shaped rotating shaft (5), locking claws (5-1), a clasping ring I (5-2), a clasping ring II (5-3) and T-shaped rotating columns (5-4), wherein the I-shaped rotating shaft (5) is rotatably connected with the locking claws (5-1), the left end of each locking claw (5-1) is fixedly connected with the clasping ring I (5-2), the right end of each locking claw (5-1) is fixedly connected with the clasping ring II (5-3), the middle part of the upper side of each locking claw (5-1) is fixedly connected with the T-shaped rotating column (5-4), two locking claws (5-1) are arranged, the two locking claws (5-1) are arranged in central symmetry, the I-shaped rotating shaft (5) is rotatably connected to the lifting lower plate (3), and a screw rod (2-1) is matched with the two clasping rings I (5-2), the sliding columns (1-7) are matched with the two clasping rings II (5-3), and the two T-shaped rotating columns (5-4) are connected in a sliding groove III on the lifting lower plate (3) in a sliding way.

7. The 5G signal test probe of claim 6, wherein: the high polymer material mixing and extruding system further comprises rotating blocks (5-5), a bidirectional screw I (5-6), gears I (5-7), gears II (5-8), adjusting motors (5-9) and locking plates (5-10), wherein the rotating blocks (5-5) are rotatably connected on the two T-shaped rotating columns (5-4), the two rotating blocks (5-5) are respectively in threaded connection with the two ends of the bidirectional screw I (5-6), the gears I (5-7) are fixedly connected to the middle parts of the bidirectional screw I (5-6), the gears I (5-7) are in meshing transmission connection with the gears II (5-8), the gears II (5-8) are fixedly connected to output shafts of the adjusting motors (5-9), the locking plates (5-10) are fixedly connected to the adjusting motors (5-9), the locking plate (5-10) is rotationally connected with the bidirectional screw I (5-6), and the lower part of the adjusting motor (5-9) is slidably connected in a chute IV on the lifting lower plate (3).

8. The 5G signal test probe of claim 7, wherein: the high polymer material mixing and extruding system also comprises a bevel gear I (2-2), a bidirectional screw II (6), a bevel gear II (6-1), a limiting ring (6-2), a sliding plate (6-3) and a fixed bearing seat (6-4), bevel gear I (2-2) fixed connection is on the output shaft of double-shaft motor (2) lower extreme, bevel gear I (2-2) and bevel gear II (6-1) meshing transmission are connected, bevel gear II (6-1) fixed connection is in the middle part of two-way lead screw II (6), the equal fixedly connected with spacing ring (6-2) in both sides at two-way lead screw II (6) middle part, the both ends of two-way lead screw II (6) all have slide (6-3) through threaded connection, the both ends of two-way lead screw II (6) rotate respectively and connect in two fixed bearing frame (6-4).

9. The 5G signal test probe of claim 8, wherein: the high polymer material mixing and extruding system further comprises two I-shaped sliding blocks (7) and two ground gripping claws (7-1), wherein the I-shaped sliding blocks (7) are connected with the sliding grooves I (1-3) in a sliding mode, the lower portion of each I-shaped sliding block (7) is fixedly connected with the ground gripping claw (7-1), the I-shaped sliding blocks (7) are attached to the sliding plates (6-3), and the number of the I-shaped sliding blocks (7) is two.

10. The 5G signal test probe of claim 9, wherein: the high polymer material mixing and extruding system further comprises a sliding seat (8), two limiting plates (8-1) and a rotating shaft (8-2), wherein the two limiting plates (8-1) are fixedly connected to the upper portion of the sliding seat (8), the rotating shaft (8-2) is rotatably connected with the two limiting plates (8-1), a limiting rod is fixedly connected to the tail end of the rotating shaft (8-2), the limiting rod is matched with the two limiting grooves in the limiting seat (1-5), and the two limiting plates (8-1) are respectively matched with the two limiting rings (6-2).

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