KR100978915B1 - Active rfid tag with body ratating type power supply switch - Google Patents

Abstract

PURPOSE: An active type RFID(Mobile Frequency ID) tag having body rotation type switch structure is provided to disunite body of the RFID tag to power unit and circuit unit and change a power switch with relative rotation of two parts thereby easily grasping state of the power switch in remote. CONSTITUTION: A top case(100) comprises a battery and purchases contact points for a pair of power supply. A bottom case(200) comprises tag PCB PCB(Printed Circuit Board) and comprises contact points for a pair of power supply connected to anode and cathode terminal of the tag PCB. A hinge structure is installed in between the upper unit and lower case and is possible to relatively rotate of the upper case and the lower case. The first of status about the upper case and the lower case is maintained, the contact points for the power supply and demand are electrically connected.

Description

Active RFID tag with body ratating type power supply switch}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an active RFID tag having a body rotary switch structure, and in particular, a body rotary switch to which a power switch is switched by relatively rotating two portions in a state in which an RFID tag body is separated into two portions of a power supply portion and a circuit portion. It relates to an active RFID tag having a structure.

Radio Frequency IDentification (RFID) is a technology for recognizing various kinds of information and surrounding situation information about the thing by wireless communication with an RFID tag attached to the thing.

According to this RFID technology, the RFID tag is attached to everything (or place) necessary (Ubiquitous), and through this, as well as identifying the basic object (Identifying), as well as surrounding environmental information (temperature, Humidity, contamination information, crack information, etc.) can be detected (Sensing) and the detected information can be centrally delivered and managed in real time through the network (Networking). Such RFID technology can be widely used in various fields of our lives, from food, livestock management, waste management, environmental management, logistics, security, access control or parking lot management.

Here, RFID tags are classified into passive and active according to the presence or absence of a battery. Passive RFID tags without batteries cannot transmit data only within a few meters from the reader because they do not have the ability to transmit data by themselves. . Such passive RFID tags are mainly used as transportation cards, access cards, or asset management cards.

On the other hand, an active RFID tag with a built-in battery can transmit data even over a distance of several tens of meters. The active RFID tag is attached to a vehicle, dangerous goods, a container, a unit load device (ULD), a pallet, etc. according to an applied service or a usage environment.

Meanwhile, when an active RFID tag is attached to an article and transported by a ship, it takes a long time to transport, and thus, a battery embedded in the RFID tag is discharged, and thus, RFID tag data cannot be delivered when necessary.

In addition to the battery discharge problem, in the case of air transportation, even the microwaves may interfere with the operation of the aircraft, so when the vehicle is mounted on the aircraft to block the microwaves from the RFID tag with the battery during transportation I'm getting rid of it.

However, in the conventional active RFID tag, there is no easy way to check the power switch to turn off the battery and whether the power is on or off easily. Not only is it cumbersome to remove or insert it upside down, but it is difficult to check the power on / off status of the RFID tag from the outside. there was.

The present invention has been made to solve the above-mentioned problems, the shape of the body before and after switching by switching the power switch by rotating the two parts relatively in a state in which the RFID tag body separated into two parts of the power supply section and the circuit section. It is an object of the present invention to provide an active RFID tag having a body rotary switch structure so that the on / off state of a power switch can be easily understood at a long distance regardless of the attachment state by changing the color or color.

An active RFID tag having a body rotary switch structure of the present invention includes an upper case having a battery housed therein and having a pair of power supply contacts electrically connected to a positive terminal and a negative terminal for power supply of the battery; The tag circuit board is accommodated, and is provided between the lower case and the upper case and the lower case having a pair of power supply contacts electrically connected to the positive and negative terminals for supplying power of the tag circuit board, respectively. It includes a hinge structure for supporting the upper case and the lower case so as to be relatively rotatable, the contact for the power supply and the power supply only when maintaining a first predetermined phase with respect to the upper case and the lower case Supply and supply contacts are electrically connected, and the upper case and the lower case is configured to be different in shape, color or shape when and when not maintaining the first phase.

In the above configuration, it characterized in that it further comprises a rotation angle limiting means for limiting the rotation of the upper case and the lower case to a predetermined range.

The apparatus may further include phase maintaining means for maintaining the upper case and the lower case in the first phase while no external force is applied.

One of the power supply contacts and one of the power supply and supply contacts are always connected by a power cable.

The first phase is characterized in that it is given in a predetermined angle range.

According to the active RFID tag having a body rotary switch structure of the present invention, the power switch can be easily turned on and off by relatively rotating the tag body separated into two parts, and thus the shape of the front and rear surfaces of the tag body By changing the color, the operator can easily grasp the on / off state of the power switch even at a distance regardless of the attachment state, thereby improving work efficiency.

1A to 1C are perspective views illustrating an appearance of an active RFID tag having a body rotary switch structure according to an embodiment of the present invention;
2A to 2C are perspective views illustrating an appearance of an active RFID tag having a body rotary switch structure according to another embodiment of the present invention;
3 is a perspective view of the active RFID tag having a body rotary switch structure according to an embodiment of the present invention with the upper half of the upper case and the lower case removed;
4 is an enlarged front view of the hinge structure portion of the active RFID tag shown in FIG. 3, respectively;
5 is an exploded perspective view of the hinge structure in the active RFID tag shown in FIG.
6A and 6B show an operating state of the hinge structure in the switched on and off states in the active RFID tag shown in FIG. 3, respectively.
7A and 7B are schematic longitudinal cross-sectional views of an active RFID tag having a body rotary switch structure according to another embodiment of the present invention, showing the operating states in the switched on and off states, respectively.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of an active RFID tag having a body rotary switch structure of the present invention.

1A to 1C are perspective views illustrating an appearance of an active RFID tag having a body rotary switch structure according to an embodiment of the present invention. As shown in FIG. 1, the body of an active RFID tag having a body rotary switch structure according to the present invention has an upper case 100 in which a battery (not shown) is accommodated and a lower case in which a tag circuit board (not shown) is accommodated. It may be made of 200, the upper case 100 and the lower case 200 is supported to allow a relative rotation by the hinge structure described later.

In the above-described configuration, the front surface 110 of the upper case 100 and the front surface 210 of the lower case 200 may have the same color (represented by the same hatching in the figure) as shown in FIG. The rear surface 120 of the upper case 100 and the rear surface 220 of the lower case 200 also have the same color (represented by the same hatching in the drawing), as shown in Figure 1b, the front surface 110, ( 210) It should have a color different from the color (expressed by different hatching in the drawing). In this configuration, when the upper case 100 and the lower case 200 have the same color as shown in FIG. 1A or 1B, the switch is turned on to indicate that battery power is being supplied to the tag circuit board. ) Is rotated with respect to the lower case 200 so that when the colors of the upper case 100 and the lower case 200 are different as shown in FIG. 1C, the switch is turned off to cut off the battery power supplied to the tag circuit board. Indicates.

In other words, according to the present invention, the switch structure for supplying battery power to the tag circuit board is implemented by rotating the body, the upper case 100 and the lower case 200 by varying the front color and the rear color of the upper case even in the distance By the color difference between the 100 and the lower case 200, it is possible to easily determine the on / off state of the current switch. The upper case 100 and the lower case 200 may be made of a synthetic resin material.

2A to 2C are perspective views illustrating an appearance of an active RFID tag having a body rotary switch structure according to another embodiment of the present invention, and an example configured to distinguish a switch on / off state by shape rather than color; It is shown. In other words, the front surface 110 'of the upper case 100' and the front surface 210 'of the lower case 200' have an associated (continuous) shape as shown in FIG. Expression). The rear surface 120 'of the upper case 100 and the rear surface 220' of the lower case 200 also have an associative (continuous) shape (represented as a shape in the drawing) as shown in FIG. It must have a different shape than its front face. In this configuration, when the shapes of the upper case 100 'and the lower case 200' are correlated (continuous) as shown in FIG. 2A or 2B, the switch is turned on to supply battery power to the tag circuit board. While the upper case 100 'is rotated relative to the lower case 200', the shape of the upper case 100 'and the lower case 200' is different (disconnected) as shown in FIG. Is off to indicate that the battery power supplied to the tag circuit board has been cut off.

In the above, the division of the on / off state of the switch can be confirmed by changing the color or shape of the front and rear of the upper case and the lower case, but can also be confirmed by changing the shape of the upper case and the lower case.

3 is a perspective view of the active RFID tag having a body rotary switch structure according to an embodiment of the present invention with the first half of the upper case and the lower case removed, and FIG. 4 is a hinge structure portion of the active RFID tag shown in FIG. 3. 5 is an exploded perspective view of the hinge structure in the active RFID tag shown in FIG. 3, and FIGS. 6A and 6B are hinges in the switched on and off states of the active RFID tag shown in FIG. This figure shows the operation of the structure.

First, as shown in FIGS. 3 to 5, in the active RFID tag having the body rotary switch structure of the present invention, the upper case 100 and the lower case 200 are each screwed in a state in which the first half and the second half are made of different bodies. It can be configured to form a body by coupling.

In the above-described configuration, the upper case 100 may be divided into a battery accommodating part 130 and a hinge structure fastening part 150 in which the battery 132 is accommodated by the partition wall 140 crossing the lower part thereof again. The lower case 200 may also be divided into a circuit board accommodating part 230 and a hinge structure fastening part 250 in which the tag circuit board 232 is received by the partition wall 240 crossing the upper part.

The battery accommodating part 130 of the upper case 100 is provided with a positive terminal connecting portion 134 and a negative terminal connecting portion 136 electrically connected to the positive terminal and the negative terminal of the battery 132, respectively.

On the other hand, the tag circuit board 232 accommodated in the circuit board accommodating portion 230 of the lower case 200 is provided with a power cable (positive and negative power cables) connector 234 for receiving battery power. . In addition, the positive terminal connecting portion 134 provided in the battery accommodating part 130 is always electrically connected to the positive terminal (not shown) of the power cable connector 234 by the positive power cable 138. On the other hand, the negative electrode terminal connecting portion 136 is extended to the hinge structure fastening portion 150 to form a contact 136a, this contact 136a is bent in a V shape so that the contact is surely maintained by elasticity have. Of course, unlike the above-described structure may be modified so that the negative terminal connecting portion 136 and the negative terminal of the power cable connector 234 is always connected electrically by the power cable.

On the other hand, each of the hinge structure fastening parts 150 and 250 of the upper case 100 and the lower case 200 is a hinge structure that allows the upper case 100 to rotate relative to the lower case 200. 300 is provided while supporting the upper case 100 and the lower case 200.

Specifically, the hinge structure 300 includes a cylindrical shaft 310 which is installed at the center of the hinge structure coupling parts 150 and 250 of the upper case 100 and the lower case 200. A portion of the outer diameter portion of the shaft 310 is chamfered (two faces are chamfered in this embodiment) 312. Hereinafter, this is referred to as the 'D-shaft' for convenience in its cross-sectional shape. A cable through hole 316 through which the positive power cable 138 described above is formed is formed at the center of the D-shaft 310, and a lower sleeve 314 is provided at the bottom thereof to prevent separation of the lower bracket to be described later. Is formed.

Next, the lower bracket 320 is coupled to the outside of the D-shaped shaft 310, and thus the shaft coupling hole 322 is formed at the center of the lower bracket 320. Furthermore, the shaft coupling hole 322 is formed in the same D shape as the outer shape of the D-shaft 310 so that the lower bracket 320 is not idle when inserted into the D-shaft 310. The lower bracket 320 also has a pair of case connecting portions 324 for fixing it to the lower case 200, and by fastening the bolts through bolt through holes formed in the respective case connecting portions 324. The lower bracket 320 is fixed to the lower case 200. Furthermore, according to this embodiment, the negative power cable 236 and the lower bracket by connecting (grounding) the negative power cable 236 together in fastening the bolt to the lower case 200 through any one bolt through hole. Electrically connect the 320, accordingly, the lower bracket 320 should be made of a metal material.

Next, a ring-shaped spacer is formed on the lower bracket 320 of the D-shaft 310 to maintain a predetermined distance between the upper bracket 350 and the lower bracket 320, which will be described later, as well as to reduce the contact area thereof. 330 is coupled to the center of the spacer 320 is a circular shaft coupling hole 332 is formed.

Next, a ring-shaped flat washer 340 is coupled to the upper portion of the spacer 330 of the D-shaft 310 to facilitate the relative rotation of the upper bracket 350 and the lower bracket 320. The shaft coupling hole 344 of 340 is made of the same D-shape as the outer shape of the D-shaft 310 so as not to idle with respect to the D-shaft 310. Reference numeral 342 denotes a lubricant receiving hole in which a lubricant such as grease is stored.

Next, the upper bracket 350 is coupled to the upper portion of the flat washer 340 of the D-shaft 310, and thus the shaft coupling hole 352 is formed at the center of the upper bracket 350. Furthermore, the shaft coupling hole 352 is formed in a circular shape so that the upper bracket 350 is idling in the state where the upper bracket 350 is inserted into the D-shaft 310. The upper bracket 350 also has a pair of case connecting portions 354 for fixing the upper bracket 100 to the upper case 100, and by fastening the bolts through bolt through holes formed in the respective case connecting portions 354. The upper bracket 350 is fixed to the upper case 100. As such, the lower bracket 320 fixed to the lower case 200 does not idle with respect to the D-shaft 310 while the upper bracket 350 fixed to the upper case 100 is the D-shaft 310. Since the upper case 100 can be rotated relative to the lower case 200 as a result of the structure that is idling with respect to. Reference numeral 356 indicates that the rotation of the upper bracket is limited to a predetermined angle range, for example, 180 °, to prevent disconnection due to the twisting of the positive power cable 138. That is, the upper bracket 350 is connected to the lower bracket 320. Based on the state rotated by 90 ° with respect to), two stopper projections are limited to 90 ° in the clockwise and counterclockwise directions, respectively, and 358 indicates the locking hole.

Next, the upper bracket 350 of the D-shape 310 is coupled to the upper bracket 350, that is, a ring-shaped stopper bracket 360 to prevent excessive rotation of the upper case 310, such a stopper The shaft coupling hole 362 of the dragon bracket 360 is made of the same D-shape as the outer shape of the D-shaft 310 so as not to be idling with respect to the D-shaft 310. Furthermore, a stopper protrusion 366 integrally bent on the outer circumferential surface of the ring body and then bent again by a predetermined length is integrally formed. 356 prevents the upper bracket 350 from excessively rotating relative to the lower bracket 320. Reference numeral 364 denotes a lubricant receiving hole in which lubricant such as grease is stored. And a locking projection that is caught by the locking hole 358 of the 350, and the locking projection 368 is rotated by 90 ° clockwise or counterclockwise with respect to the lower bracket 320. It informs the user by the sound when it is in the correct switch on or off state and maintains the state as long as no external force is applied. The.

Finally, reference numerals 370, 372, and 374 denote pan-shaped spring washers inserted above the stopper bracket 360 of the D-shaft 310, which are such spring-loaded spring washers 370, 372, 374. ) Is used to apply tension up and down in the process of the upper bracket 350 is rotated relative to the lower bracket (320). On the other hand, although not shown, the upper sleeve is formed on the upper end of the D-shaped shaft 310 to prevent the separation of the dish-type spring washers 370, 372, 374, the upper sleeve is a dish-type spring washer ( 370, 372, and 374 may be formed by hitting and unfolding the upper end of the D-shaft 310 in the inserted state.

Meanwhile, the D-shaft 310, the lower bracket 320, the flat washer 340, the upper bracket 350 and the stopper bracket 360 are all made of a conductive material, for example, a metal material.

Referring to the operation of the present invention having the above-described configuration, first, when the upper bracket 35 has a phase as shown in Figure 6a with respect to the lower bracket 320, that is, in phase, the stopper bracket 360 The stopper protrusion 366 is electrically connected to the negative electrode terminal connecting portion 136, and thus the switch is turned on by electrically connecting the D-shaft 310, the lower bracket 320, and the power cable connector 234. Accordingly, battery power is supplied to the tag circuit board 232. In this state, the first half 110 of the upper case 100 and the first half 210 of the lower case 200 are positioned on the same plane and maintain the same color as shown in FIG. You can check that it is on.

On the other hand, when the user rotates the upper case 100 with respect to the lower case 200 to turn off the switch, the upper bracket 350 is rotated to stop the rotation by the stopper protrusion 366, with the rotation The contact between the stopper protrusion 366 of the stopper bracket 360 and the contact 136a of the negative electrode terminal connecting portion 136 is released. As a result, in this state, as shown in FIG. 6B, the upper case 100 rotates only by 180 ° with respect to the lower case 200, and the rear case 120 and the lower case 200 of the upper case 100 are rotated. Since the front surface 210 is located on the same plane, it can be confirmed from a long distance that the switch is turned off by the color difference.

7A and 7B are schematic longitudinal cross-sectional views of an active RFID tag having a body rotary switch structure according to another embodiment of the present invention, respectively, showing operating states in the switched on and off states, respectively. The rotation limiting mechanism and the state maintaining mechanism for limiting excessive rotation of the case and the lower case are omitted.

In FIG. 7, reference numerals 400 and 450 denote upper and lower cases, respectively, 410 denotes a battery, 460 denotes a tag circuit board, and 440 denotes a hinge structure. Reference numerals 430 and 435 denote the positive and negative contacts for supply formed at intervals at the bottom of the upper case 400, and 420 and 425 denote the positive and negative terminals of the battery 410 and the positive contact 430 for the supply. ) And a power supply cable connecting the supply cathode contact 435, respectively. Reference numeral 470 denotes a power cable connector installed on the tag circuit board 460, and 490 and 495 denote supply and demand positive and negative contacts, respectively, which are formed at intervals on the upper end of the lower case 450. Reference numerals 480 and 485 denote power cables connecting the supply and demand positive and negative contacts 490 and 495, respectively, to the power cable connector 470.

In the above-described configuration, one of the supply contact and the supply contact may be implemented as an elastic piece, for example, an elastic piece having the same structure as the supply electrode piece of the battery of the mobile phone.

In the embodiment of FIG. 7, unlike the embodiment of FIG. 3, supply and supply of the positive and negative contacts 430 and 435, which are electrically connected to the positive and negative terminals of the battery, are both connected to the tag circuit board 460. When the upper case 400 has a phase as shown in FIG. 7B with respect to the lower case 450, the second electrode contact 490 and the supply and cathode contact 495 are separated from each other. The contact of the supply anode contact 430 and the supply cathode contact 435 are released from the supply and supply cathode contact 450 and supply and supply cathode contact 455, respectively, that is, the switch is turned off, so that the power of the battery becomes a tag circuit board. It is not supplied to 460. In this state, when the user rotates the upper case 400 relative to the lower case 450 by 180 °, the user has a phase as shown in FIG. 7A with respect to the upper case 400 and the lower case 450. In this case, the supply positive electrode contact 430 and the supply negative electrode contact 435 contact the supply positive electrode contact 490 and the supply negative electrode contact 495, that is, the switch is turned on, so that battery power is supplied to the tag circuit board. 460 is supplied.

The active RFID tag having the body rotary switch structure of the present invention is not limited to the above-described embodiment and can be modified in various ways within the scope of the technical idea of the present invention.

For example, unlike the embodiments described with reference to FIGS. 1 and 2, the switch on and off states may be externally identified by the shape difference between the upper case and the lower case, and the angle at which the switch is turned on or off is 180 degrees. It may be deformed at a suitable angle other than °.

100, 100 ': upper case, 110, 110': first half,
120, 120 ': second half, 130: battery compartment,
132: battery, 134: positive terminal connection,
136: negative terminal connection, 138: positive power cable,
140: bulkhead, 150: hinge structure fastening portion,
200: lower case, 210: first half,
220: lower half, 230: circuit board accommodating portion,
232: tag circuit board, 234: power cable connector,
236: power cable for the negative electrode,
240: bulkhead. 250: hinge fastening,
260: LED, 300: hinge structure,
310: shaft, 312: chamfer,
314: lower sleeve, 316: cable through hole,
320: lower bracket, 322: shaft coupling hole,
324: case connection, 330: spacer,
332: shaft coupling hole, 340: flat washer,
342: lubricant receiving hole, 350: upper bracket,
352: shaft coupling hole, 354: case connection,
356: stopper turning, 358: blocking hole,
360: stopper bracket, 362: shaft coupling hole,
364: lubricant reservoir, 366: stopper projection,
368: locking projection, 370, 372, 374: dish-type spring washer,
400: upper case, 410: battery,
420, 425: power cable, 430: anode contact for supply,
435: cathode contact for supply, 440: hinge structure,
450: lower case, 460: tag circuit board,
470: power cable connector, 480, 485: power cable,
490: supply-demand anode contact, 495: supply-demand cathode contact

Claims (5)

An upper case accommodating a battery, the upper case having a pair of power supply contacts electrically connected to the positive and negative terminals for power supply of the battery;
A lower case accommodating a tag circuit board and having a pair of power supply and supply contacts electrically connected to the positive and negative terminals for supplying power of the tag circuit board, respectively;
Is installed between the upper case and the lower case is made to include a hinge structure for supporting the upper case and the lower case to allow relative rotation,
The power supply contact and the power supply and supply contact are electrically connected only when maintaining a first predetermined phase with respect to the upper case and the lower case.
An active RFID tag having a body rotary switch structure configured to have a shape, color, or shape different from when the upper case and the lower case maintain the first phase and when it is not. The method of claim 1,
Active RFID tag having a body rotary switch structure further comprises a rotation angle limiting means for limiting the rotation of the upper case and the lower case to a predetermined range. The method of claim 1,
And a phase holding means for maintaining the upper case and the lower case in the first phase while no external force is applied. The method of claim 1,
An active RFID tag having a body rotary switch structure, wherein one of the power supply contacts and one of the power supply and supply contacts are constantly connected by a power cable. The method according to any one of claims 1 to 4,
The first phase is an active RFID tag having a body rotary switch structure, characterized in that the given angle range.

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