CN117353846A - Portable 5G communication check out test set that carries - Google Patents

Abstract

The invention relates to the technical field of communication detection, in particular to portable 5G communication detection equipment. The portable device has the advantages that the area of the front surface of the main body is reduced by separating the functional unit and the signal receiving unit from the front surface of the main body, so that the portable effect is achieved, and the portable device is specific: all function panels all break away from with connecting portion, the main part just need not to consider the problem of holding function panel like this, greatly reduced main part's volume, when accomodating, function panel stacks in the receiver with its operational face up's mode, just so the positive area of receiver is the positive area of occupation in the front after accomodating, just so greatly reduced the function panel accomodate the back in the positive area of occupation, and first pick-up plate and second pick-up plate are then pressed close to the main part, make whole check out test set more portable after accomodating.

Description

Portable 5G communication check out test set that carries

Technical Field

The invention relates to the technical field of communication detection, in particular to portable 5G communication detection equipment.

Background

Typical received signal strength detection circuits may be categorized according to signal detection patterns, including peak detection, RMS detection, and power detection. Peak detection refers to detecting the peak of a received signal. RMS detection refers to the detection of the root mean square value of a signal. Power detection refers to detecting the power (i.e., dBm value) of a signal.

In the field of 5G communication, detection of signal strength is particularly important, because signal strength reflects the quality of communication between a device and a base station, which directly affects the stability and speed of communication.

However, the main body of the detecting device is often a module for accommodating different functions, where the module includes a circuit module, a display screen, a control panel, etc., and for convenience of use, some modules must be disposed on the front surface or parallel to the front surface, and cannot be stacked, which results in a large volume of the main body and is very inconvenient to carry.

Disclosure of Invention

The invention aims to provide a portable 5G communication detection device, which reduces the area of the front surface of a main body by separating a functional unit and a signal receiving unit from the front surface of the main body, thereby achieving the effect of portability and solving the problem that the main body of the 5G communication detection device is overlarge in volume and inconvenient to carry.

To achieve the above object, there is provided a portable 5G communication detection apparatus, including a main body in which a working unit is provided, further including:

a connection part provided on a horizontal side of the main body;

the functional unit is arranged in a split type between the functional unit and the main body, the functional unit comprises a functional panel and an engagement part, the functional panel is additionally provided with a functional module, and the engagement part is used for being connected with the connecting part so as to fix the functional panel on the connecting part and simultaneously connect the functional module with a working unit in the main body;

the storage box is arranged at the main body and far away from the connecting part, and is used for storing the functional panel;

the first detection plate is provided with an internal signal receiving unit;

the method comprises the steps of,

the second detection plate is provided with an external signal receiving unit;

the first detection plate and the second detection plate are connected with the main body in a foldable mode;

the inner signal receiving unit and the outer signal receiving unit are connected with the working unit in the main body.

In this solution, the connection portion 110 includes a snap rail 111, the snap rail 111 is used for being connected with the snap portion 220, see fig. 3 and 4, fig. 3 shows a component part of the snap rail 111, fig. 4 shows a component part of the snap rail 220, the snap rail 111 includes an arc rail body 1111 and two snap rail bodies 1112 in an S shape, the two snap rail bodies 1112 are respectively disposed at two ends of the arc rail body 1111, actually seen from top to bottom, the two snap rail bodies 1112 are symmetrically disposed, one side of the two snap rail bodies 1112 far away from the arc rail body 1111 forms an inward first protruding end 111a, one side of the two snap rail bodies 1112 close to the arc rail body 1111 forms an outward second protruding end 111b, the snap portion 220 includes an arc plate 221, two sides of the arc plate 221 are both provided with snap plates 224, the snap plates 224 are connected with the arc plate 221 through a curved plate 223, the curved plate 223 is bent outwards, so that the snap plates 224 are outwards biased, when in use, the snap rail bodies 220 are sleeved outside the snap rail 111 from top, as shown in fig. 7, and the first protruding ends 224 and the second protruding ends 111 can only move along the vertical direction of the snap rail 111 (i.e. the first protruding ends 111b are limited).

In fig. 2, the connection portion 110 further includes a signal connection board 112, the signal connection board 112 is fixedly connected with the outer wall of the main body 100, and the outer side of the signal connection board 112 has a plurality of contact ends, the contact ends are connected with the working units inside the main body 100 through lines, the signal connection board 112 passes through the engagement track 111 to expose the contact ends, a jack is required to be formed on the arc-shaped rail body 1111 corresponding to the signal connection board 112, the arc-shaped rail body 1111 is inserted on the signal connection board 112 through the jack, the contact ends are exposed through the jack, thus, with continued reference to fig. 3, a connection pipe 230 is disposed on one side of the functional panel 210 near the engagement portion 220, and a contact 240 is slidingly connected on one side of the connection pipe 230 far from the functional panel 210, and the contact 240 is used for contacting the contact ends under the action of springs disposed in the connection pipe 230, so as to realize signal mutual transmission between the functional panel 210 and the main body 100.

Wherein, a plurality of contact ends on the signal connection board 112 are distributed along a vertical line, then the engaging portion 220 is sleeved on the engaging track 111, and then the contact 240 falls on the vertical line, so that the engaging portion 220 sliding along the engaging track 111 can drive the contact 240 to reach a designated contact end, and the engaging portion 220 can stay at any position on the engaging track 111 under the action of friction force and then slide along the engaging track 111 under the pushing of hands.

Compared with the prior art, the invention has the beneficial effects that:

in this portable 5G communication check out test set that carries, all function panel all breaks away from with connecting portion, the main part just need not to consider the problem of holding function panel like this, greatly reduced main part's volume, when accomodating, function panel stacks in the receiver with its mode that the face of operation faced upwards, the area of occupation is just the positive area of receiver after accomodating like this, the area of occupation is being positive after just so greatly reduced after function panel accomodates, and first pick-up plate and second pick-up plate then are close to the main part, make whole check out test set more portable after accomodating.

Drawings

Fig. 1 is a schematic diagram of a functional unit and a signal receiving unit of a detection device according to the present invention;

FIG. 2 is an exploded view showing the constitution of the detecting apparatus in the state of use of the present invention;

FIG. 3 is a schematic view of the composition of the snap-in track of the present invention;

FIG. 4 is a schematic diagram of a functional unit and a storage case according to the present invention;

FIG. 5 is a schematic view of the structure of the detecting plate according to the present invention;

FIG. 6 is a schematic view of the top cover structure of the present invention;

FIG. 7 is a schematic top view of the detection device of the present invention in use;

FIG. 8 is a schematic top view of the inspection apparatus of the present invention when stored;

FIG. 9 is a schematic diagram of the front structure of the detecting device in use of the present invention.

The meaning of each reference sign in the figure is:

100. a main body; 110. a connection part; 111. engaging the track; 1111. an arc-shaped rail body; 1112. engaging the rail body; 111a, a first protruding end; 111b, a second protruding end; 112. a signal connection board; 120a, a first detection plate; 120b, a second detection plate; 121. a fixing plate; 122. a flexible board; 120A, a clamping groove; 130. a top plate; 140. a bottom plate; 150. a first restriction lever; 160. a second restriction lever; 170. a top cover; 100A, a first notch; 200. a functional unit; 210. a functional panel; 220. a bite portion; 221. an arc-shaped plate; 222. a straight plate; 223. a bending plate; 224. a bite plate; 230. a connecting pipe; 240. a contact; 300. a storage box; 300A, a second notch; 400. a cabinet door; 500. a cabinet wall.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present invention, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

Typical received signal strength detection circuits may be categorized according to signal detection patterns, including peak detection, RMS detection, and power detection. Peak detection refers to detecting the peak of a received signal. RMS detection refers to the detection of the root mean square value of a signal. Power detection refers to detecting the power (i.e., dBm value) of a signal.

In the process of realizing the above functions, a plurality of functional units 200 are necessarily disposed on the surface of the main body 100, so that the area of the front surface of the main body 100 needs to be increased to accommodate the functional units 200, and the present invention provides a portable 5G communication detection device, which reduces the area of the front surface of the main body 100 by separating the functional units and the signal receiving units from the front surface of the main body 100, so as to achieve the portable effect, and the detection device in the portable state is shown in fig. 1, wherein fig. 1 shows the detection device after the functional units and the signal receiving units are accommodated.

As shown in fig. 2, fig. 2 shows the composition structure of the detection device in the use state in an exploded view, where the detection device includes a main body 100 and a functional unit 200, and further includes a storage box 300, where the storage box 300 is disposed on a horizontal side of the main body 100 and is used for storing the functional unit 200, a connection portion 110 is disposed on a side of the main body 100 away from the storage box 300, the functional unit 200 includes a functional panel 210 and an engaging portion 220, the engaging portion 220 is used for connecting with the connection portion 110 to fix the functional panel 210, and the functional panel 210 is used for enabling a working unit in the main body 100, so that the functional module carried by the functional panel 210 is connected with the working unit, and participates in a detection operation of 5G communication signal intensity, so as to implement a specific function, for example: the peak detection, RMS detection, and power detection are further provided with a first detection plate 120a and a second detection plate 120b on the front and rear surfaces of the main body 100, respectively, and an inner signal receiving unit and an outer signal receiving unit are mounted on the first detection plate 120a and the second detection plate 120b, respectively, and are connected to the working unit in the main body 100, and the first detection plate 120a and the second detection plate 120b are foldable with the main body 100.

All the functional panels 210 are separated from the connection part 110, so that the main body 100 does not need to consider the problem of accommodating the functional panels 210, the volume of the main body 100 is greatly reduced, the functional panels 210 are stacked in the storage box 300 (i.e., the functional panels 210b in a stacked state shown in fig. 9) in a manner that the operation surfaces of the functional panels are upward during storage, the area occupied by the functional panels 210 on the front surface after storage is the area occupied by the front surface of the storage box 300, the area occupied by the functional panels 210 after storage is greatly reduced, and the first detection plate 120a and the second detection plate 120b are close to the main body 100, so that the whole detection device is more portable after storage.

Specifically, as shown in fig. 2, the connection portion 110 includes a snap rail 111, the snap rail 111 is used for being connected with the snap portion 220, see fig. 3 and 4, fig. 3 shows components of the snap rail 111, fig. 4 shows components of the snap portion 220, the snap rail 111 includes an arc rail body 1111 and two snap rail bodies 1112, the two snap rail bodies 1112 are respectively disposed at two ends of the arc rail body 1111, actually seen from top to bottom, the two snap rail bodies 1112 are symmetrically disposed, one side of the two snap rail bodies 1112 far from the arc rail body 1111 forms an inward first protruding end 111a, one side of the two snap rail bodies 1112 near the arc rail body 1111 forms an outward second protruding end 111b, the snap portion 220 includes an arc plate 221, two sides of the arc plate 221 are respectively provided with a snap plate 224, the snap plate 224 is connected with the arc plate 221 through a curved plate 223, the curved plate 223 is bent outwards, so that the snap plate 224 is outwards biased, when in use, the snap portion 220 is sleeved outside the snap rail 111 from top, as shown in fig. 7, and the first protruding end 224 and the second protruding end 111b can only move along the vertical direction of the snap rail 111 (i.e. the first protruding end 111b is limited).

In fig. 2, the connection portion 110 further includes a signal connection board 112, the signal connection board 112 is fixedly connected with the outer wall of the main body 100, and the outer side of the signal connection board 112 has a plurality of contact ends, the contact ends are connected with the working units inside the main body 100 through lines, the signal connection board 112 passes through the engagement track 111 to expose the contact ends, a jack is required to be formed on the arc-shaped rail body 1111 corresponding to the signal connection board 112, the arc-shaped rail body 1111 is inserted on the signal connection board 112 through the jack, the contact ends are exposed through the jack, thus, with continued reference to fig. 3, a connection pipe 230 is disposed on one side of the functional panel 210 near the engagement portion 220, and a contact 240 is slidingly connected on one side of the connection pipe 230 far from the functional panel 210, and the contact 240 is used for contacting the contact ends under the action of springs disposed in the connection pipe 230, so as to realize signal mutual transmission between the functional panel 210 and the main body 100.

It should be noted that, after the plurality of contact ends on the signal connection board 112 are distributed along a vertical line and then the engaging portion 220 is sleeved on the engaging track 111, the contact 240 falls on the vertical line, so that the engaging portion 220 sliding along the engaging track 111 can drive the contact 240 to reach the designated contact end, where the engaging portion 220 can stay at any position on the engaging track 111 under the action of friction force and then slide along the engaging track 111 under the pushing of a hand.

As shown in fig. 5, fig. 5 shows a structure in which a first detecting plate 120a and a second detecting plate 120b are connected to a main body 100, fig. 5 shows only the first detecting plate 120a, since the second detecting plate 120b is connected to the main body 100 in the same manner as the first detecting plate 120a, not shown by the drawings, in fig. 5, a fixing plate 121 is provided on the side of the first detecting plate 120a connected to the main body 100, the fixing plate 121 is fixedly connected to the outer wall of the main body 100, the first detecting plate 120a is connected to the fixing plate 121 by a flexible plate 122, and similarly, a fixing plate 121 is provided on the side of the second detecting plate 120b connected to the main body 100, and then, the second detecting plate 120b is connected to the fixing plate 121 by a flexible plate 122, and folding of the first detecting plate 120 a/the second detecting plate 120b is achieved by the flexible feature of the flexible plate 122.

Preferably, the flexible board 122 is hollow, so that the wires connected between the inner signal receiving units/outer signal receiving units on the first detecting board 120 a/second detecting board 120b and the working units inside the main body 100 can be protected by the flexible board 122, and meanwhile, the bending of the wires is realized by reserving wires in the flexible board 122.

In use, the functional panels 210 to be used are taken out of the storage box 300, and then are sleeved on the engagement tracks 111 through the respective engagement portions 220, so that the contact 240 of each functional panel 210 is contacted with a contact end, the contact end is not limited in position, as long as the contact is achieved, a terminal for 5G communication is usually installed in a cabinet, and then the cabinet door is used for sealing so as to protect the terminal, and at the moment, the internal and external signal intensities are different under the blocking of the cabinet door 400, therefore, the first detection plate 120a and the second detection plate 120b are unfolded firstly, then the cabinet door is opened, the first detection plate 120a is placed on the inner side of the cabinet door, and then the cabinet door is closed, in this way, the signal intensities inside and outside the cabinet are detected by the inner signal receiving unit and the outer signal receiving unit mounted on the first detecting board 120a and the second detecting board 120b, respectively, as shown in fig. 7, at this time, the flexible board 122 is clamped at the gap between the cabinet door 400 and the cabinet wall 500, in order to fix the main body 100 conveniently, as shown in fig. 4, the top board 130 and the bottom board 140 are respectively disposed at the top and bottom of the main body 100, and the upper board 130 and the bottom board 140 are disposed in the vicinity of the back surface, so that the main body 100 can be adsorbed on the cabinet door 400 under the action of the upper board 130 and the lower board 140, and in order to facilitate operation, the engaging portion 220 is rotatably connected with the connecting pipe 230, so that the operation surface of the function panel 210 is turned to be opposite to the operator (i.e., the function panel 210a in the use state shown in fig. 9).

As shown in fig. 4, the top of the storage box 300 has an opening, and then a cavity is formed inside, the contour of the inside of the cavity is slightly larger than the contour of the outer side wall when the operation surface of the functional panel 210 faces upwards, and the engaging portion 220 is disposed outside the storage box 300 or extends the cavity of the storage box 300 along the horizontal side, so that the engaging portion 220 can be stored in the cavity, and in addition, the former needs to consider the existence of the connecting tube 230, so that the second notch 300A needs to be formed outside the storage box 300 corresponding to the connecting tube 230, thereby allowing the functional panel 210 to move smoothly in the cavity.

Preferably, as shown in fig. 4, a side channel is formed from the top to the bottom of the main body 100, the side channel is used for placing the engaging portion 220, and the engaging portion 220 and the functional panel 210 are kept parallel when placed, and in addition, a first notch 100A is formed on the outer side of the side channel corresponding to the connecting tube 230, and because the connecting tube 230 is located between the channel and the side channel when placed, the first notch 100A and the second notch 300A are overlapped.

In addition, as shown in fig. 4, the first limiting bar 150 and the second limiting bar 160 are symmetrically disposed at both sides of the side channel in the horizontal axis direction of the first slot 100A, respectively, and after the side channel is placed, the first limiting bar 150 is engaged with the engagement plate 224, and the second limiting bar 160 is engaged with the curved plate 223, as shown in fig. 7, thereby improving the stability of the engagement portion 220 in the side channel after the side channel is placed, because the functional panel 210 is connected with the engagement portion 220, when the stability of the engagement portion 220 is improved, the stability of the functional panel 210 is also improved.

In addition, as shown in fig. 6, a top cover 170 is provided on the top of the cavity and the side cavity, and the cavity and the side cavity are top-sealed by the top cover 170.

Further, as shown in fig. 5, a clamping groove 120A is provided on a side of the first detection plate 120A away from the main body 100 and adjacent to the outer edge, and similarly, a clamping groove 120A is provided on a side of the second detection plate 120b away from the main body 100 and adjacent to the outer edge, and when the first detection plate 120A and the second detection plate 120b are respectively inserted into the corresponding side engagement rail 1112 as shown in fig. 8, and the first protruding end 111a is engaged with the clamping groove 120A to achieve the fixing purpose.

Still further, as shown in fig. 4, two ends of the arc plate 221 extend along the axial direction of the horizontal side to form a straight plate 222, so that another connection mode exists between the engaging track 111 and the engaging portion 220, the engaging portion 220 is clamped outside the engaging track 111 by the parallel side, the clamping position can be freely selected, as shown in fig. 7, when the flexible plate 223 is dismounted, the engaging portion 220 is only pushed to the side where the engaging track 111 is located, then the flexible plate 223 is stretched outwards under the action of the second protruding end 111b, so that the engaging plate 224 can be separated from the first protruding end 111a, and then the engaging portion 220 is taken out to realize dismounting, so that the dismounting/mounting of the engaging portion 220 of the bottom layer is not influenced by the engaging portion 220 of the high layer.

Various kinds of detection circuits for 5G communication signal strength are provided, but the present embodiment does not relate to improvement of the circuit, so the connection relationship between the circuits is not described here, but for convenience of understanding, the following description is made:

different circuit modules are added into the functional panel 210, and are connected with the main body 100 in an external connection manner, and then are connected with other external circuit modules into a whole through the circuit modules in the main body 100, for example: the received signal strength detection circuit, as described in reference A CMOS Logarithmic IF Amplifier with Unbalanced Source-Coupled Pairs, employs unbalanced source coupling Pairs, cross-Coupled input stages, and parallel-connected output stages. The transistors in the unbalanced source stage coupling pair adopt two different sizes (beta and Kbeta), different input-output relation curves are obtained according to the difference of K values, the unbalanced source stage coupling pair, the cross-coupled input stage and the parallel connected output stage are additionally arranged in the three functional panels 210 at the moment, and the functional panels 210 are externally connected to the main body 100 to realize the connection among the unbalanced source stage coupling pair, the cross-coupled input stage and the parallel connected output stage.

The function panel 210 may be a display screen, an input panel with buttons, or the like.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present invention, and are not intended to limit the invention, and that various changes and modifications may be made therein without departing from the spirit and scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. Portable 5G communication detection device, it includes main part (100), be provided with the work unit in main part (100), its characterized in that still includes:

a connection part (110) provided on the horizontal side of the main body (100);

the multifunctional portable electronic device comprises a functional unit (200), wherein the functional unit (200) and a main body (100) are arranged in a split mode, the functional unit (200) comprises a functional panel (210) and a meshing part (220), a functional module is additionally arranged on the functional panel (210), the meshing part (220) is used for being connected with a connecting part (110) so as to fix the functional panel (210) on the connecting part (110), and meanwhile, the functional module is connected with a working unit in the main body (100);

a storage box (300), wherein the storage box (300) is arranged on the main body (100) far away from the connecting part (110), and the storage box (300) is used for storing the functional panel (210);

a first detection plate (120 a), wherein an internal signal receiving unit is arranged on the first detection plate (120 a);

the method comprises the steps of,

a second detection plate (120 b), wherein an external signal receiving unit is arranged on the second detection plate (120 b);

wherein, the first detection plate (120 a) and the second detection plate (120 b) are connected with the main body (100) in a foldable way;

wherein, the inner signal receiving unit and the outer signal receiving unit are connected with the working unit in the main body (100).

2. The portable 5G communication detection device according to claim 1, wherein the connection portion (110) includes a snap rail (111), the snap rail (111) includes an arc-shaped rail body (1111) and two snap rail bodies (1112), the two snap rail bodies (1112) are symmetrically disposed at two ends of the arc-shaped rail body (1111), a side of the two snap rail bodies (1112) away from the arc-shaped rail body (1111) forms an inward first protruding end (111 a), and a side of the two snap rail bodies (1112) close to the arc-shaped rail body (1111) forms an outward second protruding end (111 b);

the engagement part (220) comprises an arc-shaped plate (221), two sides of the arc-shaped plate (221) are respectively provided with an engagement plate (224), the engagement plates (224) are connected with the arc-shaped plate (221) through a bending plate (223), and the bending plate (223) bends outwards to enable the engagement plates (224) to outwards deviate;

the connecting portion (110) further comprises a signal connecting plate (112), the signal connecting plate (112) is fixedly connected with the outer wall of the main body (100), a plurality of contact ends are arranged on the outer side of the signal connecting plate (112), the contact ends are connected with working units inside the main body (100) through lines, jacks are formed in the arc-shaped rail body (1111) corresponding to the signal connecting plate (112), the arc-shaped rail body (1111) is inserted on the signal connecting plate (112) through the jacks so that the contact ends are exposed out through the jacks, a connecting pipe (230) is arranged on one side, close to the engagement portion (220), of the functional panel (210), a contact (240) is connected to one side, far away from the functional panel (210), of the connecting pipe (230) in a sliding mode, the contact (240) is connected with the functional panel (210) through lines, and the contact (240) is used for being contacted with the contact ends under the action of springs arranged in the connecting pipe (230).

3. Portable 5G communication detection device according to claim 2, characterized in that the plurality of contact ends on the signal connection board (112) are distributed along a vertical line.

4. The portable 5G communication detecting apparatus according to claim 1, wherein the first detecting board (120 a) and the second detecting board (120 b) are both provided with a fixing board (121) on a side connected with the main body (100), the fixing board (121) is fixedly connected with an outer wall of the main body (100), and the first detecting board (120 a)/the second detecting board (120 b) are connected with the corresponding fixing board (121) through a flexible board (122).

5. The portable 5G communication detection device of claim 4, wherein the flexible board (122) is hollow inside.

6. The portable 5G communication detecting apparatus according to claim 1, wherein the top of the storage box (300) has an opening, and a cavity is formed inside, and a second notch (300A) is formed at the outside of the storage box (300) corresponding to the connection pipe (230).

7. The portable 5G communication detecting apparatus according to claim 6, wherein a side channel is provided from the top to the bottom of the main body (100), the side channel is used for placing a snap-in portion (220), and the snap-in portion (220) and the functional panel (210) are kept parallel when placed;

the outer side of the side cavity channel is provided with a first notch (100A) corresponding to the connecting pipe (230), and the first notch (100A) and the second notch (300A) are overlapped.

8. The portable 5G communication detecting apparatus according to claim 7, wherein a first restricting lever (150) and a second restricting lever (160) are symmetrically disposed on both sides of the first notch (100A) in the horizontal axis direction in the side channel, respectively, the first restricting lever (150) is used for being engaged with the engaging plate (224), and the second restricting lever (160) is used for being engaged with the curved plate (223).

9. The portable 5G communication detecting apparatus according to claim 4, wherein the first detecting plate (120A) and the second detecting plate (120 b) are disposed at a side far from the main body (100) and adjacent to the outer edge, and are each provided with a clamping groove (120A).

10. Portable 5G communication detection device according to claim 2, characterized in that both ends of the arc-shaped plate (221) are provided with straight plates (222) along the axial direction of the horizontal side.