CN214151754U - RFID temperature measurement label adopting UV (ultraviolet) gluing mode - Google Patents

Abstract

The utility model discloses an adopt RFID temperature measurement label of UV mucilage binding mode, including body, debugging pin, UV colloid, shell bottom rigid coupling has the base plate, and base plate top surface and shell inside enclose into one supply UV colloid block, and can be vertical free gliding slip chamber, and the UV colloid is spacing to its vertical removal by limit structure, is equipped with a plurality of elastic components between UV colloid bottom surface and the base plate top surface. The utility model discloses the beneficial effect who reaches is: encapsulate RFID temperature measurement label through the UV colloid, the rigidity of RFID temperature measurement label body has been promoted, and install the UV colloid in the shell, further promoted RFID temperature measurement label's shock resistance, set up the elastic component in addition, when can making the UV colloid receive the impact through the elastic component, can carry out the shock attenuation protection, through setting up the elasticity portion, make the shell when receiving the impact, through the elastic deformation of elasticity portion, reduce the impact that the shell received.

Description

RFID temperature measurement label adopting UV (ultraviolet) gluing mode

Technical Field

The utility model relates to a RFID temperature measurement label technical field specifically is an adopt RFID temperature measurement label of UV mucilage binding mode.

Background

Radio Frequency Identification (RFID) technology is a non-contact automatic identification technology that automatically identifies a target object and acquires related data by a radio frequency signal. When an article with an electronic tag passes through a specific data reader-writer, the tag is activated by the reader-writer and transmits data carried in the tag to the reader-writer and a data processing system through radio waves, so that the automatic data acquisition work is completed. With the rapid development of the radio frequency identification technology, the radio frequency identification technology has been widely applied to the field of logistics, and in the cold-chain logistics industry, the radio frequency identification technology has been adopted to wirelessly track the temperature. The electronic tag used in cold-chain logistics integrates a temperature sensor, obtains temperature data in real time through the temperature sensor, and stores the temperature data into a memory of the electronic tag. The user can read useful data such as temperature, time and the like in the electronic tag by using the reader, so that temperature change in the processes of product transportation, distribution and the like can be monitored, and responsibility confirmation of quality accidents is facilitated.

In the prior art, the RFID temperature measurement tag is not protected after being installed, so that the RFID temperature measurement tag is easy to be damaged due to impact.

In order to solve the above problems, we propose an RFID temperature measurement tag using a UV adhesive bonding method.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to overcome prior art's defect, provide an adopt RFID temperature measurement label of UV mucilage binding mode, in order to solve above-mentioned technical problem, the utility model provides a following technical scheme:

the utility model provides an adopt RFID temperature measurement label of UV mucilage binding mode, body including RFID temperature measurement label, be equipped with the debugging pin on the body, the body encapsulates in the UV colloid, just the UV colloid bottom is worn out to the debugging pin, the UV colloid is installed in the shell, shell bottom rigid coupling has the base plate, base plate top surface and shell inside enclose into one supply UV colloid block, and can vertical free gliding sliding chamber, the UV colloid carries on spacingly by limit structure to its vertical removal, be equipped with a plurality of elastic components between UV colloid bottom surface and the base plate top surface, elastic component elasticity is replaced UV colloid and drive UV colloid shifts up.

As a further optimization of the above technical solution, the elastic member is a damping spring vertically installed in the sliding cavity, and two ends of the damping spring in the elastic direction elastically abut against the top surface of the substrate and the bottom surface of the UV gel respectively.

As a further optimization of the above technical solution, the substrate is provided with a clearance groove through which the debugging pin can freely pass when moving.

As above technical scheme's further optimization, limit structure is including locating the spacing ring in the shell, the spacing ring is located the UV colloid top, be equipped with in the shell and supply the mounting groove that the spacing ring was installed and the internal diameter is greater than the sliding chamber internal diameter, the coaxial jump ring groove that is equipped with on the mounting groove inner wall, the jump ring is installed to the jump ring inslot, the jump ring is used for spacing the spacing ring.

As a further optimization of the above technical solution, the outer wall of the housing is provided with an elastic part formed by rotating around the axis thereof, and the upper end of the elastic part is fixedly connected with the edge of the top of the housing.

Compared with the prior art, the utility model discloses the beneficial effect who reaches is: encapsulate RFID temperature measurement label through the UV colloid, the rigidity of RFID temperature measurement label body has been promoted, and install the UV colloid in the shell, further promoted RFID temperature measurement label's shock resistance, set up the elastic component in addition, when can making the UV colloid receive the impact through the elastic component, can carry out the shock attenuation protection, through setting up the elasticity portion, make the shell when receiving the impact, through the elastic deformation of elasticity portion, reduce the impact that the shell received.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic structural diagram of an RFID temperature measurement tag using UV adhesive bonding of the present invention;

fig. 2 is a schematic perspective view of the housing of the present invention;

FIG. 3 is a schematic partial cross-sectional view of the three-dimensional structure of FIG. 2;

in the figure: 1-sliding cavity, 2-clearance groove, 3-debugging pin, 4-damping spring, 5-substrate, 6-elastic part, 7-shell, 8-snap spring, 9-body, 10-UV colloid, 11-limiting ring, 12-mounting groove and 13-snap spring groove.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are presented herein only to illustrate and explain the present invention, and not to limit the present invention.

Examples

As shown in fig. 1-3, an adopt RFID temperature measurement label of UV mucilage binding mode, body 9 including RFID temperature measurement label, be equipped with debugging pin 3 on body 9, body 9 encapsulates in UV colloid 10, and debugging pin 3 wears out UV colloid 10 bottom, UV colloid 10 is installed in shell 7, shell 7 bottom rigid coupling has base plate 5, base plate 5 top surface and shell 7 are inside to enclose into one and supply UV colloid 10 block, and can vertical free gliding sliding chamber 1, UV colloid 10 is spacing by limit structure to its vertical removal, be equipped with a plurality of vertical damping spring 4 of installing in sliding chamber 1 between UV colloid 10 bottom surface and base plate 5 top surface, damping spring 4 elasticity direction both ends respectively support base plate 5 top surface and UV colloid 10 bottom surface, damping spring 4 elasticity supports UV colloid 10 and drive UV colloid 10 and move up.

In this embodiment, offer on the base plate 5 and supply debugging pin 3 to remove the clearance groove 2 that can freely pass through, through clearance groove 2, the external equipment of being convenient for passes through clearance groove 2, and then tests debugging pin 3.

In this embodiment, limit structure is including locating spacing ring 11 in shell 7, spacing ring 11 is located UV colloid 10 top, be equipped with in the shell 7 and supply the installation of spacing ring 11, and the internal diameter is greater than the mounting groove 12 of 1 internal diameter in sliding chamber, the coaxial jump ring groove 13 that is equipped with on the 12 inner walls of mounting groove, jump ring 8 is installed to jump ring inslot 13, jump ring 8 is used for spacing ring 11, the terminal surface supports spacing ring 11 top surface under the jump ring 8, when UV colloid 10 receives damping spring 4's elastic force effect and when removing up, UV colloid 10 top surface offsets with 11 bottom surfaces of spacing ring, and then carry on spacingly.

In this embodiment, the outer wall of the housing 7 is provided with the elastic portion 6 which is formed by rotating around the axis, the upper end of the elastic portion 6 is fixedly connected with the top edge of the housing 7, and when the housing 7 is impacted, the impact on the housing 7 can be reduced by the elastic deformation of the elastic portion 6.

The utility model discloses a theory of operation: when installation UV colloid 10, at first with UV colloid 10 as for sliding chamber 1 in, then with spacing ring 11 card income mounting groove 12 in, install jump ring 8 in jump ring groove 13 again, thereby it is spacing to carry out UV colloid 10, base plate 5 is installed in temperature measuring equipment, when receiving vibrations or impact, elastic component 6 weakens vibrations or strikes the impact to UV colloid 10 through elastic deformation, in addition UV colloid 10 receives when vertically strikeing, the elastic compression through damping spring 4 reduces vibrations or strikes the influence to body 9 in the UV colloid 10, and then can carry out multiple protection to RFID temperature measurement label body 9.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (5)

1. An RFID temperature measurement label adopting a UV adhesive bonding mode comprises a body (9) of the RFID temperature measurement label, a debugging pin (3) is arranged on the body (9), it is characterized in that the body (9) is packaged in a UV colloid (10), the debugging pin (3) penetrates out of the bottom of the UV colloid (10), the UV colloid (10) is arranged in the shell (7), the bottom of the shell (7) is fixedly connected with the substrate (5), the top surface of the substrate (5) and the inner part of the shell (7) enclose a sliding cavity (1) which is used for clamping the UV colloid (10) and can vertically and freely slide, the UV colloid (10) is limited by a limiting structure in vertical movement, a plurality of elastic pieces are arranged between the bottom surface of the UV colloid (10) and the top surface of the substrate (5), the elastic piece elastically abuts against the UV colloid (10) and drives the UV colloid (10) to move upwards.

2. The RFID temperature measurement tag adopting the UV adhesive bonding mode as claimed in claim 1, wherein the elastic member is a damping spring (4) vertically installed in the sliding cavity (1), and two ends of the damping spring (4) in the elastic force direction elastically abut against the top surface of the substrate (5) and the bottom surface of the UV adhesive (10) respectively.

3. The RFID temperature measurement tag adopting the UV adhesive bonding mode as claimed in claim 1, wherein the substrate (5) is provided with a clearance groove (2) for the debugging pin (3) to freely pass through when moving.

4. The RFID temperature measurement tag adopting the UV adhesive bonding mode according to claim 1, wherein the limiting structure comprises a limiting ring (11) arranged in a shell (7), the limiting ring (11) is positioned above a UV adhesive body (10), an installation groove (12) for installing the limiting ring (11) and having an inner diameter larger than that of the sliding cavity (1) is arranged in the shell (7), a clamp spring groove (13) is coaxially arranged on the inner wall of the installation groove (12), a clamp spring (8) is arranged in the clamp spring groove (13), and the clamp spring (8) is used for limiting the limiting ring (11).

5. The RFID temperature measurement label adopting the UV adhesive bonding mode as claimed in claim 1, wherein the outer wall of the shell (7) is provided with an elastic part (6) formed by rotating around the axis thereof, and the upper end of the elastic part (6) is fixedly connected with the top edge of the shell (7).

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