JP5558372B2 - Heat resistant wireless tag - Google Patents

Description

In particular, the present invention is used by attaching to a container (melting container) used in a high-temperature environment, and wirelessly sending an identification code to an antenna disposed at a location away from this container, The present invention relates to a heat resistant wireless tag for identification.

At present, in chemical factories and the like, when processing high-temperature solid materials and molten materials, melting containers are used, and these may be moved for use preparation (for example, preheating), operation, repair, etc. At present, most of the operation plans are carried out in the operator manual. Therefore, in order to automate these operations and realize a work load reduction, a repair plan based on actual usage in units of containers, and creation of usage rotation, it is essential to manage the containers in use.

JP 2006-72804 A

The present inventor attached a widely sold IC tag (wireless tag) as described in Patent Document 1 to a container (for example, a melting container) for injecting a high temperature material, and moved in the factory. Although the IC tag that is widely used usually has a protective cover that is made of synthetic resin such as polycarbonate, the IC cover is widely used. There was a problem that the case became tattered by heat and could not be continuously used continuously.
Therefore, although it was tried to be housed and used in a heat-resistant ceramic case, at a high frequency (for example, 900 MHz band) used in an IC tag, radio waves do not pass through the ceramic case or are remarkably used. There was a problem that it could not be used due to attenuation.

The present invention has been made in view of such circumstances, and is attached to a container that transports a high-temperature raw material in a factory, has heat resistance against heat irradiation during operation, and has good radio wave permeability and heat resistance wireless. The purpose is to provide tags.

The heat-resistant wireless tag according to the present invention that meets the above-described object is used by being attached to a container that conveys a high-temperature material used in a factory, and has a transmitter that transmits an identification code inside, and is surrounded by thermoplastic or thermosetting. Wireless tag covered with a protective cover made of synthetic plastic,
The periphery of the protective cover was covered with a heat-resistant glassy coating mainly composed of silicate glass through a primer layer.

Here, examples of the thermosetting resin include an epoxy resin, a phenol resin, a melamine resin, a urea resin, an unsaturated polyester resin, an alkyd resin, a polyurethane, and a thermosetting polyimide. Engineering plastics (for example, polycarbonate, polyacetal, polybutylene terephthalate, polyethylene terephthalate), super engineering plastics (polyphenylene sulfide, polytetrafluoroethylene, polysulfone) and the like.

The heat-resistant glassy film mainly composed of silicate glass is represented by a general formula of M ₂ O · nSiO ₂ , and M is any one of Na, K, Li, and Cs in a liquid state before coating. For example, 0.01 to 1.0 mol / kg of ammonium ion and 0.01 to 1.0 mol / kg of halogen in the presence of metal alkoxide (MSnon) mainly composed of alkali silicate (20 to 50% by weight). It is preferable to use what was diluted with alcohol as needed to what added ion. Ammonium ions and halogen ions are added to improve permeability and are not necessarily essential components.
The primer layer may be any organic or inorganic material as long as it has good adhesion to the base material of the protective cover and the heat-resistant glassy coating on the surface, and also has heat resistance. It is preferable to use an inorganic primer layer containing an inorganic resin such as a resin as a solid content.

Here, the thickness of the primer layer is preferably 5 to 10 μm, and the total thickness of the primer layer and the heat-resistant glassy film is preferably in the range of 15 to 40 μm. However, as long as heat resistance and non-peelability can be ensured. Even if the thickness is out of the range, the present invention is applied.

In the heat resistant wireless tag according to the present invention, the heat resistant glassy film is preferably Terios Coat (registered trademark) NP360G released by Nikko Co., Ltd. This Terios Coat NP360G has the properties that the main component is SiO ₂ , the heat resistant temperature is 700 ° C., and the specific gravity is 1.05.

Further, in the heat resistant wireless tag according to the present invention, when the protective cover includes a receiving unit that receives an external radio wave and uses the electric power of the transmitting unit, or in the protective cover, the transmission It may be a case where a battery for supplying power to the unit is provided.
The mounting position of the heat-resistant wireless tag is a portion where the temperature of the container is the lowest (usually the side of the container) and is not covered with a cover such as metal. More preferably, the part where the ambient temperature is 100 ° C. or lower on the side surface of the container is preferable.

Note that the surface of the mounted heat-resistant wireless tag is preferably exposed. This directly receives the heat rays from the surroundings, which are covered with a heat-resistant glassy coating on the surface. If the surface of the heat-resistant wireless tag is covered with, for example, a heat-resistant sheet, the raw material droplets adhere to the heat-resistant wireless tag, and the flight of radio waves from the heat-resistant wireless tag becomes worse.

Since the heat-resistant wireless tag according to the present invention covers the periphery of a protective cover made of synthetic resin with a heat-resistant vitreous film mainly composed of silicate glass through a primer layer, the ambient temperature rising instantaneously, Heat resistance has been improved against heat rays, making it possible to use heat-resistant wireless tags at high temperatures.

As the material of the protective cover, for example, polycarbonate, polyacetal, polybutylene terephthalate, polyphenylene sulfide, polytetrafluoroethylene, and polysulfone, which are called engineering plastics or super engineering plastics, have a sufficient radio wave transmission property. The performance was ensured by covering the heat-resistant glassy coating.

In the heat-resistant wireless tag according to the present invention, a heat-resistant glassy film is attached to a container that conveys a high-temperature material, and an antenna, a reader / writer, and a personal computer for control connected to the reader / writer are provided, thereby the current position of the container, And movement status can be monitored.

It is explanatory drawing of the identification system using the heat resistant radio | wireless tag which concerns on one embodiment of this invention. It is explanatory drawing of the heat resistant radio | wireless tag. (A), (B) is explanatory drawing which shows the other attachment method of the heat resistant radio | wireless tag.

Subsequently, a heat-resistant wireless tag embodying the present invention and an identification system using the same will be described.
As shown in FIG. 1, a heat-resistant wireless tag 11 according to an embodiment of the present invention is attached to a side portion of a container 10 that transports a high-temperature material used in a factory, and is separated from the heat-resistant wireless tag 11 by about 6 m. A heat-resistant curtain 12 made of cloth was placed, and an antenna 13 was placed behind the curtain. The antenna 13 is connected to a reader / writer (controller) 14, and the reader / writer 14 is connected to a control PC 15.

In this embodiment, as shown in FIGS. 1 and 2, the heat-resistant wireless tag 11 is attached to the opening 17 of the iron cover cover 16 provided on the side of the container 10 via the support member 18. ing. The heat-resistant wireless tag 11 has a case (protective cover) 19 made of polycarbonate (an example of a thermoplastic synthetic resin) having a size of 51 × 42 × 122 mm, and a transmission unit (not shown) housed in the case 19. doing. The case 19 may be a thermosetting synthetic resin.

In using the heat-resistant wireless tag 11, it is preferable not to provide a heat insulating cover on the front side. When the heat insulating cover is provided, when splashes of high-temperature material or the like adhere to the heat insulating cover, the heat insulating cover is a material that blocks radio waves. Accordingly, the heat-resistant wireless tag 11 is attached to the outside of the support member 18 or directly to the support member 18, and the heat-resistant wireless tag 11 itself is exposed to the outside.
The temperature inside or around the cover 16 is 50 to 60 ° C. (that is, 100 ° C. or less). The temperature of the other part of the container 10 is 280 to 370 ° C. on the outer wall of the container 10 due to preheating of the container 10 before use and accumulation of molten metal during use.

The heat-resistant wireless tag 11 has a transmitter and a receiver in the case 19, receives the radio wave transmitted from the antenna 13 at the receiver, uses it as power, and puts a predetermined identification code inside from the transmitter Transmitting from the provided antenna. The output of the radio wave transmitted from the heat-resistant wireless tag 11 is extremely weak and can be received by the antenna 13 disposed within about 8 m. The output of the antenna 13 is transmitted to the reader / writer 14 and demodulated to demodulate the identification code. It is sent to. Accordingly, the container 10 provided with the heat-resistant wireless tag 11 is in a predetermined angular position in plan view (that is, the heat-resistant wireless tag 11 faces toward the antenna 13), and the antenna 13 is within about 8 m. When approaching within the range, the identification code transmitted from the heat-resistant wireless tag 11 can be recognized. Note that a battery may be provided in the case to serve as a power source for the transmitter.

The thickness of the synthetic resin case 19 is, for example, 2 to 4 mm, and the outer surface thereof is coated with a heat-resistant glassy film 22 mainly composed of silicate glass via a primer layer 21. Yes. In this embodiment, SS primer (trade name) sold by Nikko Co., Ltd. is used for this primer layer 21, but the primer layer 21 is familiar with the synthetic resin used as the case 19 (that is, has good bonding properties). As long as the heat-resistant glassy coating 22 applied to the surface is familiar and has a certain degree of heat resistance, it may be an organic or inorganic material. In this embodiment, an inorganic primer material is used.

Specifically, 0.025 to 0.035 kg / m ³ of the above-described SS primer is applied to the surface of a case 19 made of synthetic resin (polycarbonate) and dried to form a primer layer 21 on which the above-mentioned Terios coating is applied. NP360G is applied in an amount of 0.015 to 0.025 kg / m ³ . Here, if the primer layer 21 is omitted, the bondability between the heat-resistant glassy coating 22 and the case 19 may be deteriorated and may be partially peeled off.

The primer layer 21 and the heat-resistant glassy coating 22 are made of an insulating material, pass high-frequency UHF band, and do not decompose or evaporate even when irradiated with high-temperature heat rays. A film having a low thermal conductivity (thickness is preferably 15 to 40 μm) is formed. As a result, the internal synthetic resin is thermally protected.

From the antenna 13, the radio wave of 100 ms was emitted, and the radio wave was irradiated toward the heat resistant wireless tag 11 at an interval of 200 ms. The radio wave emitted from the antenna 13 is received by the receiving unit of the heat-resistant wireless tag 11, and the weak radio wave including the ID signal (identification code) is transmitted from the transmitting unit of the heat-resistant wireless tag 11 using it as power. The weak radio wave including the ID signal is received by the antenna 13, sent to the reader / writer 14, and sent as a digital signal to the control PC 15. The control PC 15 identifies the container 10 in which the weak radio wave was emitted.
The reception range of weak radio waves emitted from the heat-resistant wireless tag 11 is preferably 6 to 12 m or less. If the output of the weak radio wave is too strong, the signal of the heat resistant wireless tag 11 provided in the container 10 that is far away is received, and the position of the container 10 cannot be specified.

FIG. 3 shows another mounting method of the heat-resistant wireless tag 11 when the flange 24 is provided around the container 24. An L-shaped mounting bracket 26 is provided on the lower surface of the flange 25. The heat-resistant wireless tag 11 is attached to the lower part of the device via the mounting base 27. Thereby, even if the high temperature material overflows from the container 24, the heat resistant wireless tag 11 under the flange 25 is protected.

In the above embodiment, the primer layer 21 and the heat-resistant glassy coating 22 have been specified and described. However, the material can be changed without changing the gist of the present invention.
Further, a commercially available wireless tag before being coated with the heat-resistant glassy coating 22 can be used, which reduces the cost and facilitates disposable use.

10: container, 11: heat-resistant wireless tag, 12: heat-resistant curtain, 13: antenna, 14: reader / writer, 15: PC for control, 16: cover cover, 17: opening, 18: support member, 19: case, 21: Primer layer, 22: Heat-resistant glassy coating, 24: Container, 25: Flange, 26: Mounting bracket, 27: Mounting base

Claims (6)

A wireless tag that is attached to a container that transports high-temperature materials used in a factory, has a transmitter that transmits an identification code inside, and is covered with a protective cover made of thermoplastic or thermosetting synthetic resin. There,
A heat-resistant wireless tag, wherein the periphery of the protective cover is covered with a heat-resistant vitreous film mainly composed of silicate glass through a primer layer. 2. The heat-resistant wireless tag according to claim 1, wherein a total thickness of the primer layer and the heat-resistant vitreous film is in a range of 15 to 40 μm. 3. The heat-resistant wireless tag according to claim 1, wherein the heat-resistant glassy film is Terios Coat (registered trademark). The heat-resistant wireless tag according to any one of claims 1 to 3, wherein the protective cover includes a receiving unit that receives an external radio wave and uses it as power of the transmitting unit. Heat-resistant wireless tag. The heat-resistant wireless tag according to any one of claims 1 to 3, wherein a battery for supplying power to the transmitter is provided in the protective cover. The heat-resistant wireless tag according to any one of claims 1 to 5, wherein the heat-resistant wireless tag is attached to the side of the container at a position where the ambient temperature is 100 ° C or less and is open to the outside. A heat-resistant wireless tag characterized by

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