RFID electronic tag with a pressure-resistant structure

By using a modular structural design and combining support components, the problem of RFID electronic tags being easily deformed and damaged under pressure has been solved, achieving better pressure resistance and convenient installation.

CN224472038UActive Publication Date: 2026-07-07DALIAN SHENGFENG ADHESIVE PROD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DALIAN SHENGFENG ADHESIVE PROD
Filing Date
2025-08-18
Publication Date
2026-07-07

AI Technical Summary

Technical Problem

Existing RFID electronic tags are susceptible to deformation due to external pressure due to their integrated structural design, which can lead to internal cracks. Furthermore, the suspended structure at the center of the box is also prone to deformation and damage under pressure.

Method used

It adopts a modular structural design, including a support base plate, a sealing cover plate, and a support tube. Through the combination of components such as side grooves, top insertion grooves, and sealing channels, multi-layer support and sealing are formed. The main label body is fixed, squeezed, and sealed by extrusion strips and insertion columns to prevent collapse.

Benefits of technology

This improves the pressure resistance of RFID electronic tags, prevents damage from squeezing, and enhances the ease of installation and overall pressure resistance.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of RFID electronic tags with compression resistance structure, it is related to RFID electronic tag field, including support base plate, the two side edges of support base plate are symmetrically provided with side through slot, the two side edges of support base plate are symmetrically fixed with installation side strip, the top surface of installation side strip is uniformly provided with fixed through-hole, the top surface of support base plate is horizontally buckled with sealing cover plate, the top surface of sealing cover plate is horizontally pasted with label paste, the top surface of support base plate is symmetrically provided with insertion top groove, the top surface of support base plate is horizontally provided with sealing groove, the inside edge of support base plate is horizontally fixedly connected with inner support frame, the inside edge of support base plate is uniformly fixedly connected with support pipe body, the inside edge of support base plate is horizontally clamped with main label body, using split structure makes installation use more convenient, and in combination with parcel support structure makes the overall compression resistance effect better.
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Description

Technical Field

[0001] This utility model relates to the field of RFID electronic tag technology, specifically an RFID electronic tag with a pressure-resistant structure. Background Technology

[0002] RFID electronic tags work by enabling contactless data communication between a reader and the tag to identify targets. RFID has a wide range of applications, including animal microchips, car anti-theft devices, access control, parking management, production line automation, and material management.

[0003] When using current electronic tags, the integrated structural design makes the plate structure susceptible to external compression deformation, leading to internal cracks and rendering it unusable. Furthermore, the separate box-mounted structure, with its center suspended, can also deform under external pressure, causing internal compression and damage. Utility Model Content

[0004] The purpose of this utility model is to provide an RFID electronic tag with a pressure-resistant structure to solve the problems mentioned in the background art. When using current electronic tags, due to the integrated structure design, the plate structure will be deformed by external compression, resulting in internal cracks and rendering it unusable. In addition, the separate box-mounted structure, since the center of the box is also suspended, will still deform under external compression, causing internal compression and damage.

[0005] To achieve the above objectives, this utility model provides the following technical solution:

[0006] An RFID electronic tag with a pressure-resistant structure includes a supporting base plate. Symmetrical side passages are formed on both sides of the supporting base plate. Mounting side strips are symmetrically fixed on both sides of the supporting base plate. Fixing through holes are evenly distributed on the top surface of the mounting side strips. A sealing cover plate is horizontally fastened to the top surface of the supporting base plate. A label sticker is horizontally affixed to the top surface of the sealing cover plate. A top insertion groove is symmetrically formed on the top surface of the supporting base plate. A sealing channel is horizontally formed on the top surface of the supporting base plate. An inner support frame is horizontally fixedly connected to the inner side of the supporting base plate. The inner side of the supporting base plate is evenly fixedly connected to… The device includes a support tube, a main label body horizontally snapped onto the inner side of the support base plate, through holes evenly distributed on the top surface of the main label body, a sealing frame fixedly mounted on the bottom surface of the sealing cover plate, an insertion base rod symmetrically fixedly connected to the bottom surface of the sealing cover plate, a snap-fit ​​wedge snapped onto one side of the insertion base rod, a compression frame fixedly mounted on the bottom surface of the sealing cover plate, a compression strip fixedly mounted on the bottom surface of the compression frame, insertion columns evenly fixedly connected to the bottom surface of the sealing cover plate, a snap-fit ​​ring fixedly mounted on the outer side of the insertion column, and a ring groove horizontally opened on the inner wall of the support tube.

[0007] In a preferred embodiment of this utility model, the side through grooves are symmetrically arranged in pairs on the two symmetrical sides of the supporting base plate near the edge, and one end of the side through groove extends into the interior of the top groove to maintain connection. The mounting side strips are symmetrically fixed at the bottom of both sides of the supporting base plate.

[0008] In a preferred embodiment of this utility model: the plug-in top grooves are symmetrically arranged in pairs on the top surface of the support base plate near the four corners, the sealing groove is horizontally opened at the top opening of the support base plate near the inner side, the inner support frame is arranged in a square shape, and the inner support frame is horizontally fixedly arranged on the inner side of the support base plate near the bottom surface.

[0009] In a preferred embodiment of this utility model, there are multiple supporting tubes, which are arranged in parallel with each other. The multiple supporting tubes are arranged in a straight line at equal intervals on the inner center line of the supporting base plate, and the top of the supporting tubes is open.

[0010] In a preferred embodiment of this utility model: the bottom edge of the main label body is aligned with the top surface of the inner support frame, the number of through holes is consistent with the number of support tubes, and each through hole is fitted onto the outer side of the support tube. The bottom end of the sealing frame is inserted into the inner side of the sealing channel. The bottom rod is symmetrically fixed on the bottom surface of the sealing cover near the four corners, and its bottom end is inserted into the inner side of the top groove. One end of the snap-fit ​​wedge is snapped into the inner side of the side through groove.

[0011] In a preferred embodiment of this utility model: the bottom surface of the extrusion strip is extruded and set at the top edge of the main label body; the arrangement of the insertion columns is consistent with that of the support tube body; and the bottom ends of the insertion columns are all inserted into the inner side of the support tube body; the outer side of the snap ring is horizontally snapped into the inner side of the ring groove.

[0012] Compared with the prior art, the beneficial effects of this utility model are:

[0013] This invention involves horizontally placing the main label body into the top channel of the supporting base plate, with its edge positioned horizontally on the top surface of the inner supporting frame. Multiple supporting tubes are inserted through through holes to position the main label body. A sealing cover is then snapped onto the top surface of the supporting base plate, and the bottom insertion rod is correspondingly inserted into the insertion groove. Side snap-fit ​​wedges are engaged within side grooves for a secure installation. Finally, the bottom end of the sealing frame is inserted into the sealing channel to create a seal. When pressed downwards, the extrusion frame, along with the extrusion strip at the bottom, is pressed towards the top of the main label, thus fixing the main label inside the support base plate. The insertion column is then inserted into the support tube, forming a fixed installation. The sealing isolation provided by the external support base plate and sealing cover effectively creates a pressure-resistant effect. The support column structure in the middle prevents collapse and damage caused by compression. The modular structure makes installation and use more convenient, and the combined wrapping support structure improves the overall pressure resistance. Attached Figure Description

[0014] Other features, objects, and advantages of this invention will become more apparent from the following detailed description of non-limiting embodiments with reference to the accompanying drawings:

[0015] Figure 1 A three-dimensional structural diagram of an RFID electronic tag with a pressure-resistant structure;

[0016] Figure 2 A schematic diagram showing the structural details of the three-dimensional connection of a support base plate for an RFID electronic tag with a pressure-resistant structure;

[0017] Figure 3 A structural schematic diagram showing the three-dimensional connection details of the main tag body of an RFID electronic tag with a pressure-resistant structure;

[0018] Figure 4 This is a structural schematic diagram showing the three-dimensional connection details of a sealing cover plate for an RFID electronic tag with a pressure-resistant structure.

[0019] In the diagram: 1. Support base plate; 2. Side through groove; 3. Side mounting strip; 4. Fixing through hole; 5. Sealing cover plate; 6. Label sticker; 7. Insertion top groove; 8. Sealing channel; 9. Inner support frame; 10. Support tube body; 11. Main label body; 12. Through hole; 13. Sealing frame body; 14. Insertion bottom rod; 15. Snap-on inclined block; 16. Extrusion frame body; 17. Extrusion rubber strip; 18. Insertion column body; 19. Snap-on ring; 20. Ring snap groove. Detailed Implementation

[0020] Please see Figure 1 In this embodiment of the present invention, an RFID electronic tag with a pressure-resistant structure includes a supporting base plate 1. Side through grooves 2 are symmetrically opened on both sides of the supporting base plate 1. Mounting side strips 3 are symmetrically fixed on both sides of the supporting base plate 1. The side through grooves 2 are symmetrically opened in pairs on the two symmetrical sides of the supporting base plate 1 near the edge. One end of the side through groove 2 extends into the interior of the insertion top groove 7 to maintain communication. The mounting side strips 3 are symmetrically fixed at the bottom of both sides of the supporting base plate 1. Fixing through holes 4 are evenly opened on the top surface of the mounting side strips 3. A sealing cover plate 5 is horizontally fastened to the top surface of the supporting base plate 1. A label sticker 6 is horizontally pasted on the top surface of the sealing cover plate 5.

[0021] Please see Figure 2-4In this embodiment of the present invention, an RFID electronic tag with a pressure-resistant structure is provided, wherein the top surface of the supporting base plate 1 is symmetrically provided with insertion top grooves 7, the top surface of the supporting base plate 1 is horizontally provided with sealing channels 8, and the inner side of the supporting base plate 1 is horizontally fixedly connected with an inner support frame 9. The insertion top grooves 7 are symmetrically arranged in pairs near the four corners of the top surface of the supporting base plate 1, the sealing channels 8 are horizontally opened near the inner side of the top opening of the supporting base plate 1, and the inner support frame 9 is arranged in a U-shape and is horizontally fixedly arranged on the inner side of the supporting base plate 1 near the bottom surface. Support tubes 10 are uniformly fixedly connected to the inner side of the base plate 1. Multiple support tubes 10 are arranged in parallel to each other, forming a straight line at equal intervals along the inner centerline of the base plate 1. The top of each support tube 10 is open. A main label 11 is horizontally snapped onto the inner side of the base plate 1. Through holes 12 are uniformly formed on the top surface of the main label 11. A sealing frame 13 is fixedly installed on the bottom surface of the sealing cover plate 5. A plug-in bottom rod 14 is symmetrically fixedly connected to the bottom surface of the sealing cover plate 5. One side of the plug-in bottom rod 14 is snapped with a fastener. The bottom edge of the inclined block 15 and the main label body 11 are aligned with the top surface of the inner support frame 9. The number of through holes 12 is consistent with the number of support tubes 10, and each through hole 12 is fitted onto the outer side of the support tube 10. The bottom end of the sealing frame 13 is inserted into the inner side of the sealing channel 8. The bottom rod 14 is symmetrically fixed on the bottom surface of the sealing cover plate 5 near the four corners, and its bottom end is inserted into the inner side of the top groove 7. One end of the inclined block 15 is snapped into the inner side of the side passage groove 2. The bottom surface of the sealing cover plate 5 is fixed with a compression frame. 16. An extrusion strip 17 is fixedly installed on the bottom surface of the extrusion frame 16. Insertion columns 18 are uniformly fixedly connected to the bottom surface of the sealing cover plate 5. A snap ring 19 is fixedly installed on the outer side of the insertion column 18. A ring groove 20 is horizontally opened on the inner side wall of the support tube 10. The bottom surface of the extrusion strip 17 is extruded and installed at the top edge of the main label body 11. The arrangement of the insertion columns 18 is consistent with that of the support tube 10. The bottom ends of the insertion columns 18 are all inserted into the inner side of the support tube 10. The outer side of the snap ring 19 is horizontally snapped into the inner side of the ring groove 20.

[0022] The working principle of this utility model is as follows:

[0023] The main label body 11 is placed horizontally inside the top channel of the support base plate 1, with its edge positioned horizontally on the top surface of the inner support frame 9. The top ends of multiple support tubes 10 are inserted through the through holes 12, forming a positioning and installation operation for the main label body 11. Then, the sealing cover plate 5 is snapped onto the top surface of the support base plate 1, and the bottom insertion rod 14 is correspondingly inserted into the insertion top groove 7. The side snapping wedge 15 is engaged inside the side through groove 2 to form a fixed installation operation, allowing the sealing frame 13 to... The bottom insertion is set inside the sealing groove 8 to form a sealing effect. When pressed downward, the extrusion frame 16, along with the extrusion strip 17 at the bottom, is pressed towards the top of the main label body 11, thus fixing the main label body 11 inside the support base plate 1. The insertion column 18 is correspondingly inserted into the support tube 10 to form a fixed installation. Due to the sealing isolation of the external support base plate 1 and the sealing cover plate 5, an effective pressure resistance effect is formed. The support column structure in the middle position prevents it from collapsing and causing extrusion damage.

[0024] The above description is only a preferred embodiment of the present utility model, but the protection scope of the present utility model is not limited thereto. Any equivalent substitutions or changes made by those skilled in the art within the technical scope disclosed in the present utility model, based on the technical solution and the inventive concept of the present utility model, should be included within the protection scope of the present utility model.

Claims

1. An RFID electronic tag with a pressure-resistant structure, comprising a supporting base plate (1), characterized in that, The supporting base plate (1) has symmetrical side through grooves (2) on both sides. The supporting base plate (1) has symmetrically fixed mounting side strips (3) on both sides. The mounting side strips (3) have uniformly fixed through holes (4) on the top surface. The supporting base plate (1) has a horizontally fastened sealing cover plate (5) on the top surface. The sealing cover plate (5) has a horizontally pasted label sticker (6) on the top surface. The supporting base plate (1) has symmetrically opened insertion top grooves (7) on the top surface. The supporting base plate (1) has a horizontally opened sealing channel (8) on the top surface. The supporting base plate (1) has a horizontally fixed inner support frame (9) on the inner side. The supporting base plate (1) has a uniformly fixed support tube body (10) on the inner side. The supporting base plate (1) has a horizontally snapped inner side. The main label body (11) has a through hole (12) evenly opened on the top surface of the main label body (11). A sealing frame (13) is fixedly installed on the bottom surface of the sealing cover plate (5). A plug-in bottom rod (14) is symmetrically fixedly connected to the bottom surface of the sealing cover plate (5). A snap-fit ​​inclined block (15) is snapped on one side of the plug-in bottom rod (14). A compression frame (16) is fixedly installed on the bottom surface of the sealing cover plate (5). A compression rubber strip (17) is fixedly installed on the bottom surface of the compression frame (16). A plug-in column (18) is evenly fixedly connected to the bottom surface of the sealing cover plate (5). A snap-fit ​​ring (19) is fixedly installed on the outer side of the plug-in column (18). A ring groove (20) is horizontally opened on the inner wall of the support tube (10).

2. The RFID electronic tag with a pressure-resistant structure according to claim 1, characterized in that, The side through grooves (2) are symmetrically opened in pairs on the two symmetrical sides of the supporting base plate (1) near the edge, and one end of the side through groove (2) extends into the interior of the insertion top groove (7) to maintain a connection.

3. The RFID electronic tag with a pressure-resistant structure according to claim 1, characterized in that, The mounting side strips (3) are symmetrically fixed to each other at the bottom of both sides of the support base plate (1), and the top grooves (7) are symmetrically opened in pairs on the top surface of the support base plate (1) near the four corners.

4. An RFID electronic tag with a pressure-resistant structure according to claim 1, characterized in that, The sealing channel (8) is horizontally opened at the top opening of the support base plate (1) near the inner side. The inner support frame (9) is set in a square shape and is horizontally fixed at the inner side of the support base plate (1) near the bottom surface.

5. An RFID electronic tag with a pressure-resistant structure according to claim 1, characterized in that, The number of the support tubes (10) is multiple, and the multiple support tubes (10) are arranged in parallel with each other. The multiple support tubes (10) are arranged in a straight line at equal intervals on the inner center line of the support base plate (1). The top of the support tube (10) is open. The bottom edge of the main label body (11) is connected to the top surface of the inner support frame (9). The number of through holes (12) is consistent with the number of support tubes (10), and the through holes (12) are all connected to the outer side of the support tubes (10).

6. An RFID electronic tag with a pressure-resistant structure according to claim 1, characterized in that, The bottom end of the sealing frame (13) is inserted into the inner side of the sealing channel (8).

7. An RFID electronic tag with a pressure-resistant structure according to claim 1, characterized in that, The bottom rod (14) is symmetrically fixed on the bottom surface of the sealing cover plate (5) near the four corners, and its bottom end is correspondingly inserted into the inner side of the top groove (7).

8. An RFID electronic tag with a pressure-resistant structure according to claim 1, characterized in that, One end of the snap-fit ​​oblique block (15) is snapped into the inner side of the side through groove (2), the bottom surface of the extrusion strip (17) is extruded into the top edge of the main label body (11), the arrangement of the insertion column (18) is consistent with that of the support tube body (10), and the bottom ends of the insertion column (18) are all inserted into the inner side of the support tube body (10) in a corresponding manner, and the outer side of the snap-fit ​​ring (19) is horizontally snapped into the inner side of the ring groove (20).