CN111313917B - 5G mobile communication signal inductor - Google Patents

Abstract

The invention discloses a 5G mobile communication signal inductor, which structurally comprises a signal receiving end, a signal inductor and an adaptor, wherein the signal receiving end is arranged at the rear end position of the signal inductor, the adaptor is embedded at the front end position of the signal inductor, the position deviation of the adaptor caused by external extrusion can be avoided through the matching of a reinforcing mechanism on the adaptor and an antiskid plate, when the adaptor is extruded to generate the position deviation in an insertion opening of a mobile phone, a reset block can be pulled to reset through an elastic sheet on the antiskid block, the transient poor contact phenomenon can be prevented after the position deviation of the adaptor is generated through a contact mechanism on the adaptor, and as a guide block can be opened and closed along with the movement of a guide rod, a contact on the guide block can be always contacted with the bottom of the insertion opening of the mobile phone, the adaptor is prevented from being deviated to a reset time gap, a phenomenon of poor contact occurs.

Description

5G mobile communication signal inductor

Technical Field

The invention relates to the field of 5G, in particular to a 5G mobile communication signal sensor.

Background

The 5G signal sensor is a device for assisting a mobile phone to receive signals or stimuli and respond, and is often installed inside the mobile phone in a plug-in manner, and the 5G signal sensor can detect signals and convert the detected signals into information output in a required form so as to meet the requirement of information transmission, based on the above description, the inventor finds that the existing 5G mobile communication signal sensor mainly has the following defects, for example:

because stone material sculpture workman often can closely contact with the stone material at the during operation to the cell-phone in the pocket of placing frequently takes place to collide with the stone material easily, then causes the inside structure of cell-phone to produce short-lived slight deformation easily through the extrusion of stone material to the cell-phone, so repeatedly then makes the junction of 5G signal inductor and cell-phone take place the skew easily, thereby leads to the condition that the 5G signal inductor is to the reception ability decline of signal.

Disclosure of Invention

In view of the above problems, the present invention provides a 5G mobile communication signal sensor.

In order to achieve the purpose, the invention is realized by the following technical scheme: the 5G mobile communication signal sensor structurally comprises a signal receiving end, a signal sensor and an adaptor, wherein the signal receiving end is installed at the rear end of the signal sensor, and the adaptor is embedded at the front end of the signal sensor.

As a further optimization of the invention, the adapter comprises a conducting rod, a combining rod, a reinforcing mechanism, a contact mechanism and an anti-slip plate, wherein the combining rod is fixedly embedded with the reinforcing mechanism, the reinforcing mechanism is installed inside a groove of the conducting rod, the contact mechanism is hinged with the bottom of the conducting rod, the anti-slip plate and the combining rod are integrated, and the number of the reinforcing mechanisms is four, and the four reinforcing mechanisms are symmetrically distributed on the left side and the right side of the combining rod in a group.

As a further optimization of the invention, the reinforcing mechanism comprises an outer frame, a fixing block and a rebound strip, wherein the fixing block is in clearance fit with the outer frame, one end of the rebound strip is embedded and fixed on the inner wall of the outer frame, the other end of the rebound strip is connected with the outer wall of the fixing block, and the rebound strip is made of spring steel with strong elasticity.

As a further optimization of the invention, the antiskid plate comprises a bottom plate and antiskid blocks, the antiskid blocks are fixedly embedded on the outer side surface of the bottom plate, two groups of antiskid blocks and the bottom plate are arranged, the antiskid blocks and the bottom plate are uniformly and symmetrically distributed on the left side and the right side of the two combination rods, and the outer side surface of the antiskid blocks is of an arc structure.

As a further optimization of the invention, the anti-skid block comprises a connecting block, a movable ring, a reset block and an elastic sheet, the reset block is hinged with the connecting block through the movable ring, the elastic sheet is arranged between the reset block and the movable block, and the elastic sheet is made of spring steel with higher elasticity.

As a further optimization of the invention, the reset block comprises a friction increasing surface, a connecting block and a linkage block, wherein the inner side of the friction increasing surface is embedded and fixed on the outer surface of the connecting block, the inner side of the connecting block is attached to the outer surface of the linkage block, and the friction increasing surface is made of butadiene acrylonitrile rubber with high density.

As a further optimization of the invention, the contact mechanism comprises a bearing ring, guide blocks and contacts, the guide blocks are hinged with the bearing ring, the contacts are movably clamped at the bottom positions of the guide blocks, ten contacts are arranged, and five contacts are a group of guide blocks uniformly distributed at the bottom positions of the guide blocks at the two sides.

As a further optimization of the invention, the contact comprises a board surface, additional contact strips and bottom blocks, wherein the additional contact strips are embedded and fixed at the side positions of the board surface, the bottom blocks and the board surface are of an integrated structure, and two groups of contact strips are arranged and symmetrically distributed at the left side and the right side of the board surface.

As a further optimization of the invention, the touch strip comprises a conducting wire, a shell and a main conductor, wherein the conducting wire and the main conductor are in an integrated structure, the main conductor penetrates through the inner position of the shell, ten conducting wires are arranged, and five conducting wires are uniformly distributed on two sides of the main conductor in a group and are symmetrically distributed.

The invention has the following beneficial effects:

1. through the cooperation of reinforcing mechanism and the antiskid ribbed tile on the adapter, can avoid the adapter because outside extrusion causes the phenomenon of position skew, can extrude the combination pole through reinforcing mechanism, thereby make the antiskid ribbed tile on the combination pole closely laminate with the inner wall of inserted hole on the cell-phone, when the adapter receives the extrusion and takes place the position skew in the inserted hole of cell-phone, elasticity piece pulling reset block through on the non slipping spur can make it reset, so can make the adapter reset, the effectual adapter of having avoided receives the outside phenomenon that the position skew appears that extrudees easily.

2. The contact mechanism on the adapter can prevent the short bad contact phenomenon from occurring after the position of the adapter deviates, and the guide block can be opened and closed along with the movement of the conduction rod, so that the contact on the guide block can be always contacted with the bottom of a mobile phone insertion hole, and the bad contact phenomenon of the adapter in the time gap from deviating to reset is avoided.

Drawings

Fig. 1 is a schematic structural diagram of a 5G mobile communication signal sensor according to the present invention.

FIG. 2 is a schematic top view of an adaptor according to the present invention.

Fig. 3 is a schematic view of the internal structure of the reinforcing mechanism of the present invention.

FIG. 4 is a schematic view of the cleat of the present invention viewed partially from above.

FIG. 5 is a top view of the cleat of the present invention.

Fig. 6 is a schematic structural view of the reset block rotating 90 ° clockwise.

FIG. 7 is a schematic top view of the contact mechanism of the present invention.

Fig. 8 is a schematic top view of the contact of the present invention.

FIG. 9 is a schematic view of the top view of the inside of the touch bar of the present invention.

In the figure: the device comprises a signal receiving end-1, a signal inductor-2, an adapter-3, a conducting rod-31, a combining rod-32, a reinforcing mechanism-33, a contact mechanism-34, an antiskid plate-35, an outer frame-331, a fixed block-332, a rebound strip-333, a bottom plate-351, an antiskid block-352, a connecting block-a 1, a movable ring-a 2, a reset block-a 3, an elastic sheet-a 4, a friction increasing surface-a 31, a connecting block-a 32, a linkage block-a 33, a bearing ring-341, a guide block-342, a contact-343, a plate surface-b 1, a contact increasing strip-b 2, a bottom block-b 3, a lead-b 21, a shell-b 22 and a main conductor-b 23.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

As shown in fig. 1-6:

the invention provides a 5G mobile communication signal inductor which structurally comprises a signal receiving end 1, a signal inductor 2 and an adapter 3, wherein the signal receiving end 1 is installed at the rear end position of the signal inductor 2, and the adapter 3 is embedded at the front end position of the signal inductor 2.

Wherein, the adapter 3 includes conduction pole 31, combination pole 32, strengthening mechanism 33, contact mechanism 34, antiskid ribbed tile 35, combination pole 32 and strengthening mechanism 33 are embedded and are connected, strengthening mechanism 33 installs inside the recess of conduction pole 31, contact mechanism 34 and the bottom hinged joint of conduction pole 31, antiskid ribbed tile 35 and combination pole 32 are the integration mechanism, strengthening mechanism 33 is equipped with four, and four are a set of symmetric distribution in the left and right sides position of combination pole 31, can promote the inseparable laminating of inner wall of antiskid ribbed tile 35 and object.

Wherein, reinforcing mechanism 33 includes frame 331, fixed block 332, resilience strip 333, fixed block 332 and frame 331 clearance fit, the one end of resilience strip 333 inlays admittedly in the inner wall of frame 331, and the other end of resilience strip 333 is connected with the outer wall of fixed block 332, resilience strip 333 adopts the spring steel material that elasticity is stronger, can promote to carry out the rigidity with frame 331 external connection's object.

The anti-slip plate 35 comprises a bottom plate 351 and anti-slip blocks 352, the anti-slip blocks 352 are embedded on the outer side surface of the bottom plate 351, the anti-slip blocks 352 and the bottom plate 351 are provided with two groups, the left side and the right side of the two combination rods 32 are uniformly distributed symmetrically, and the outer side surface of the anti-slip blocks 352 is of an arc-shaped structure, so that the anti-slip plates can be easily scratched into an object.

The anti-slip block 352 comprises a connecting block a1, a movable ring a2, a reset block a3 and an elastic sheet a4, the reset block a3 is hinged to the connecting block a1 through the movable ring a2, the elastic sheet a4 is installed between the reset block a3 and the movable block a1, the elastic sheet a4 is made of spring steel with high elasticity, and when the reset block a3 is squeezed by external force, the reset block a3 which can be deflected can be pulled to reset through tensile force generated by the elastic sheet a4 on the reset block a 3.

The reset block a3 comprises a friction increasing surface a31, a linking block a32 and a linkage block a33, the inner side of the friction increasing surface a31 is embedded in the outer surface of the linking block a32, the inner side of the linking block a32 is attached to the outer surface of the linkage block a33, the friction increasing surface a31 is made of butadiene acrylonitrile rubber with high density, the friction increasing surface a31 is of a continuous fold structure, and is matched with the butadiene acrylonitrile rubber with high density, so that the reset block a3 can be further prevented from being displaced due to external extrusion.

The detailed use method and action of the embodiment are as follows:

in the invention, as a stone carving worker is easy to frequently collide with stone when working, the structure in the mobile phone can generate transient slight deformation, and the connection part between the adapter 3 on the signal inductor 2 and the mobile phone can easily deviate repeatedly, when the adapter 3 on the signal inductor 2 is inserted into an insertion hole on the mobile phone, the outer frame 331 can generate outward thrust through the rebounding strip 333 in the reinforcing mechanism 33, so that the outer frame 331 can push the connecting rod 32, therefore, the antiskid plate 35 on the connecting rod 32 can be tightly attached to the inner wall of the insertion hole on the mobile phone, the connection between the adapter 3 and the insertion hole on the mobile phone can be firmer, when the position deviation occurs in the insertion hole on the mobile phone due to extrusion of the adapter 3, the elastic sheet a4 on the antiskid block 352 pulls the reset block a3 to reset the mobile phone, through the increase friction face a31 that is the fold structure on reset block a3 can further prevent that adapter 3 from because the phenomenon of position excursion appears in the outside extrusion, and can cooperate elastic piece a4 pulling reset block a3 to reset to make adapter 3 reset, avoided adapter 3 to receive the outside extrusion position excursion appear, lead to the reception ability decline of signal receiving terminal 1 to the signal.

Example 2

As shown in fig. 7-9:

the contact mechanism 34 includes a receiving ring 341, two guide blocks 342, and two contacts 343, the guide blocks 342 are hinged to the receiving ring 341, the contacts 343 are movably engaged with the bottom surface of the guide blocks 342, the two guide blocks 342 are symmetrically distributed on the receiving ring 341 and can be connected with the bottom of an object all the time, the contacts 343 are ten, and five of the contacts are uniformly distributed at the bottom positions of the guide blocks 342 on both sides, and can swing along with the extrusion of the guide blocks 342.

The contact 341 includes a board surface b1, a contact increasing bar b2, a bottom block b3, the contact increasing bar b2 is embedded in the side position of the board surface b1, the bottom block b3 and the board surface b1 are integrated, the contact increasing bar b2 is provided with two groups, and the contact increasing bar b2 is symmetrically distributed at the left and right side positions of the board surface b1, and can generate inclination through the extrusion force of an object to the contact increasing bar, so that the contact area of the contact increasing bar to the object can be increased.

Wherein, increase touch strip b2 and include wire b21, casing b22, main conductor b23, wire b21 and main conductor b23 are the integral structure, main conductor b23 runs through the inside position in casing b22, wire b21 is equipped with ten, and five are a set of even both sides at main conductor b23 and are the symmetric distribution, can make the signal finally all collect on main conductor b23, avoided the inhomogeneous phenomenon of signal transmission.

The detailed use method and action of the embodiment are as follows:

in the invention, after the position of the adapter 3 is deviated, the bottom of the adapter 3 is separated from the bottom of the inner wall of the insertion hole on the mobile phone, so that short bad contact phenomenon can occur before the reset of the adapter 3, the problems can be effectively solved through the contact mechanism 34 on the adapter 3, the guide block 342 can be opened and closed along with the deviation of the conducting rod 31, so that the contact 343 on the guide block 342 can be always contacted with the bottom of the inner wall of the insertion hole on the mobile phone, the contact b2 on the contact 343 can be inclined through the attachment of the side surface of the contact 343 and the bottom of the insertion hole on the mobile phone, so that the contact surface of the contact to an object can be enlarged, and then the lead b21 on the touch increasing bar b2 can finally collect signals on the main conductor b23, thereby preventing the phenomenon of uneven signal transmission and avoiding the time gap when the adapter 3 is deviated to the reset, a phenomenon of poor contact occurs.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims (4)

1. The utility model provides a 5G mobile communication signal inductor, its structure includes signal receiving terminal (1), signal inductor (2), adapter (3), signal receiving terminal (1) is installed in the rear end position of signal inductor (2), its characterized in that: the joint head (3) is embedded at the front end of the signal inductor (2);

the joint head (3) comprises a conduction rod (31), a combination rod (32), a reinforcing mechanism (33), a contact mechanism (34) and an anti-skid plate (35), the combination rod (32) is fixedly connected with the reinforcing mechanism (33) in an embedded mode, the reinforcing mechanism (33) is installed inside a groove of the conduction rod (31), the contact mechanism (34) is hinged to the bottom of the conduction rod (31), and the anti-skid plate (35) and the combination rod (32) are integrated;

the reinforcing mechanism (33) comprises an outer frame (331), a fixing block (332) and a resilience strip (333), wherein the fixing block (332) is in clearance fit with the outer frame (331), one end of the resilience strip (333) is embedded and fixed on the inner wall of the outer frame (331), and the other end of the resilience strip (333) is connected with the outer wall of the fixing block (332);

the anti-skid plate (35) comprises a bottom plate (351) and anti-skid blocks (352), the anti-skid blocks (352) are embedded and fixed on the outer side surface of the bottom plate (351), two groups of anti-skid blocks (352) and the bottom plate (351) are arranged, and the anti-skid blocks and the bottom plate are uniformly and symmetrically distributed on the left side and the right side of the two combination rods (32);

the anti-skid block (352) comprises a connecting block (a1), a movable ring (a2), a reset block (a3) and an elastic sheet (a4), the reset block (a3) is hinged with the connecting block (a1) through the movable ring (a2), and the elastic sheet (a4) is installed between the reset block (a3) and the movable block (a 1);

the reset block (a3) comprises a friction increasing surface (a31), a connecting block (a32) and a linkage block (a33), wherein the inner side of the friction increasing surface (a31) is embedded in the outer surface of the connecting block (a32), and the inner side of the connecting block (a32) is attached to the outer surface of the linkage block (a 33).

2. The 5G mobile communication signal sensor according to claim 1, wherein: the contact mechanism (34) comprises a bearing ring (341), a guide block (342) and a contact (343), the guide block (342) is hinged with the bearing ring (341), and the contact (343) is movably clamped at the bottom position of the guide block (342).

3. The 5G mobile communication signal sensor according to claim 2, wherein: the contact (341) comprises a plate surface (b1), a touch increasing strip (b2) and a bottom block (b3), wherein the touch increasing strip (b2) is embedded in the side position of the plate surface (b1), and the bottom block (b3) and the plate surface (b1) are of an integrated structure.

4. The 5G mobile communication signal sensor according to claim 3, wherein: the contact increasing strip (b2) comprises a lead (b21), a shell (b22) and a main conductor (b23), wherein the lead (b21) and the main conductor (b23) are of an integrated structure, and the main conductor (b23) penetrates through the inner position of the shell (b 22).

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