JPH0694192A - Method and system for managing gas container - Google Patents

Abstract

PURPOSE:To facilitate the address confirmation delivery management and recovery management of gas containers by mounting a data transmitter body in which gas container management data is set, and reading the data from a relay device and transferring it to a data processing device for data processing. CONSTITUTION:A memory 1a in which the control data of gas containers are set, a control part 1b, a parallel/serial data transformer part 1c, a modulator/ demodulator part 1d, and a power part 1f are all incorporated in one chip IC, and the entire IC is sealed in a resin case to constitute a data carrier 1 as a data transmitter. The data carrier 1 is mounted firmly on the gas containers with steel band, and the gas containers are put in service. Then the data transmitted from the data carrier 1 is read from a handy terminal 2 as a data relay device through communication by radio, the data read is inputted into a data processing device 3 through an interface cable 2K1, and the data processing is made by the data processing device 3.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas container management method and management system for managing the location of gas containers.

[0002]

2. Description of the Related Art Gases generally distributed in the market, such as propane gas, acetylene gas, oxygen gas and nitrogen gas, are first filled in a gas container at a filling factory, and then transported by a delivery vehicle to each of the affiliated stores. Then, the products are delivered from each of these sales outlets to final customers such as homes and businesses. In addition, the empty gas containers collected by each dealer are collected by the collection / delivery vehicle of the filling factory and transported to the filling factory. Then, the system is such that gas is refilled and sent again to each store. That is, the gas container circulates among the filling factory, the store, and the customer. The gas container circulating in this way is
It is obligatory to confirm the location for safety management. Also, at the filling factory, if the accurate location of the gas container can be grasped at all times, it is possible to prevent long-term stay at the gas container dealer or customer, which leads to improvement of the gas container circulation rate and There is an advantage in that there is no need to stock extra gas containers in case of a shortage of gas containers. Therefore, at the filling factory, based on the container number that the gas container has uniquely, data such as shipping date, collection date, store number, etc. is entered in the ledger every time it is shipped or collected, or the data is stored in the computer using the keyboard. Manage by entering. More recently, a method of attaching a bar code label to a gas container and inputting bar code data read by a reader into a computer for management is also practiced.

[0003]

However, the method of writing data in a ledger or inputting it to a computer with a keyboard is a procedure for filling in a ledger based on a handwritten slip or performing computer input. For this reason, it was troublesome twice and the labor was enormous.
In addition, mistakes in filling in slips and ledgers and input mistakes using the keyboard occurred so frequently that it was far from accurate confirmation of the location of the gas container. Also,
In the method using the bar code label, the gas container is considerably heavy, and therefore it cannot be expected to be handled carefully during transportation, and therefore, the bar code label may be damaged and become unreadable. In addition, the environment in which the gas container is handled may be outdoors exposed to sunlight, wind and rain, or in a factory where machine oil is scattered, which deteriorates the printing ink on the bar code label and makes it unreadable or misread due to dirt. Is inevitable. The present invention is aimed at overcoming such problems, and minimizes the number of handwriting slips and entries in a ledger, and the data input work to a computer by a keyboard as much as possible, thereby reducing the number of man-hours. The purpose is to provide a gas container management method and management system that can reduce the number of entries and eliminate confusion of management data due to entry errors and input errors, and can reliably confirm the location of gas containers and manage shipping and collection. I am trying.

[0004]

In order to solve the above problems, the present invention sets gas container management data in a data transmitter and attaches the data transmitter in which the gas container management data is set to a gas container. , The gas container management data transmitted by the data transmitter is read by the data relay device, the gas container management data read by the data relay device is transferred to the data processing device, and the data received by the gas container management data is transferred. A gas container management method in which data processing is performed by a processing device. Further, a data transmitter having a memory for storing the gas container management data and a transmitter for transmitting the data set in the memory, a reader for reading the data transmitted by the data transmitter, and the data are stored. A data relay device having a memory; and a data processing device for receiving the gas container management data read by the data relay device to perform data processing, wherein the data transmitter is attached to the gas container. Alternatively, the data transmitter has a data receiving unit, and the data relay unit has a data writing unit to the data transmitter. Further, the data transmission / reception between the data transmitter and the data relay device is performed by using radio in the radio frequency band.

[0005]

The operation of the present invention is as follows. Data is set by writing predetermined data such as the gas container number, gas type, maximum weight, and store number in the memory of the data transmitter (hereinafter referred to as the data carrier). The data carrier on which this data has been set is attached to the gas container. To read the data set in the data carrier, a data relay device (hereinafter referred to as a handy terminal) is brought close to the data carrier to receive the data transmitted by radio in the radio frequency band. The received data is stored in the memory of the handy terminal. The data processing device receives the data stored in the memory of the handy terminal and performs the required processing. If necessary, the handy terminal is used to write data to the memory of the data carrier attached to the gas container.

[0006]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a system configuration diagram of the present invention, which is drawn horizontally. 2 is an external view of a data carrier, FIG. 3 is an external view of a state in which the data carrier is attached to a gas container with a steel band as an example, and FIG. 4 is an external view of a handy terminal, which is drawn horizontally. . FIG. 5 shows a printout format of the gas container temporary receipt.

In FIG. 1, reference numeral 1 is a device configuration diagram of a data carrier. Of these, 1a is a memory in which management data of the gas container is set. In this embodiment, the EPRO is an electrically rewritable memory.
M is used. Reference numeral 1b is a control unit for controlling the data carrier 1, 1c is a parallel / serial data (P / S) conversion unit for converting parallel / serial data of data output from the memory 1a or written in the memory 1a, Reference numeral 1d is a modulation / demodulation unit that performs modulation and demodulation for data transmission, 1e is an antenna coil that receives data transmission and power supply energy, which will be described later, and a power supply unit 1f. Except for the antenna coil 1e, the memory 1a, the control unit 1b, the parallel
Serial data (P / S) converter 1c, modulator / demodulator 1
d, the power supply unit 1f are all integrated into a one-chip IC,
As shown in FIG. 2, the whole is sealed in a resin case.
The data carrier 1 is sealed by the resin case.
Has excellent environmental resistance to water, dirt, ultraviolet rays, and the like.

Reference numeral 2 is a device configuration diagram of a handy terminal. Of these, 2a receives a high frequency emitted from the antenna coil 1e of the data carrier 1, transmits write data to the memory 1a of the data carrier 1, and further transmits the data carrier. 1 is an antenna coil that generates magnetic energy for supplying power source energy to 1. Two
Reference numeral b is an oscillating unit that generates a high frequency to be transmitted to the antenna coil 2a. The antenna coil 2a and the oscillation portion 2b is formed in a cylindrical casing with a controller (not shown), the data read and write unit 2 ₃ is connected to the main body serving handy terminal 2 by a connection cord 2k ₃ as (see FIG. 4) There is. Reference numeral 2c is a modulation / demodulation unit that demodulates high frequency waves received by the antenna coil 2a and modulates transmission data to be written in the memory 1a of the data carrier 1, 2d is a serial / parallel data (S / P) conversion unit, and 2e is device control 2f is a memory, which is composed of a RAM that is a writable memory at any time, and its storage is backed up by a battery of a power supply unit described later. Reference numeral 2g is a printer for printing a temporary receipt issued when the gas container is collected, which is configured in a housing separate from the handy terminal 2, which is the main body, and has a connection cord 2
Connected by k ₂ . 2h is an input unit for inputting data and has a display unit (2 ₂ shown in FIG. 4). 2i is a power supply unit, which is operated by a battery. 2j is an interface circuit, and the connection uses RS-232C which is a standard interface. Reference numeral 2k ₁ is a connection cord for connecting the interface circuit 2j and a data processing device 3 described later.

3 is a device configuration diagram of the data processing device,
A host computer 3a for performing data processing, a data writer 3b for receiving data from the host computer 3a and writing the data in the memory 1a of the data carrier 1 for setting data, and a host computer 3a.
The printer 3c that outputs the processed data of

FIG. 2 is an external perspective view of a data carrier 1 as an example of the data transmitter. This data carrier 1 is formed into a small one having a width, depth and height within 10 mm, and has an insertion hole 1'at its lower part. A stainless steel band 4 is inserted through the insertion hole 1 ', and the steel band 4 is wound around and attached to the valve portion 5'of the gas container 5 as shown in FIG. As described above, the data carrier 1 is not easily detached from the gas container even during the distribution process by using the steel band made of stainless steel which is strong against rust and does not easily break.

FIG. 4 is an external perspective view of the handy terminal 2. The handy terminal 2 is formed to have a size and weight that can be operated by hand. In FIG, 2 ₁ is composed of a 0-9 numeric keys and various function keys and alphabet keys be input key. Among them, the function key is a data read key for instructing data read of the data carrier 1, a data write key for writing data to the data carrier 1, a print key for instructing printout, and data output to the data processing device 3. It consists of output keys and cursor keys. Reference numeral 2 ₂ is a display unit using liquid crystal, and the data input using the input keys 2 ₁ and the read data of the data carrier 1 are displayed. 2 ₃ is a data read-write unit for reading and writing data in the data carrier 1, the antenna coil 2a as described above
An oscillating portion 2b and a controller (not shown) are built in, the entire casing is formed in a cylindrical shape, and is connected to the handy terminal 2 which is a main body by a connecting cord 2k ₃ . 2 ₄ is a spigot of the connection cord is connected to a data processing device 3 by the connection cord 2k _1. Two
g is a printer for printing a temporary receipt to be issued during the gas container collection, as described above, although the body serving handy terminal 2 is connected by a connecting cord 2k ₂ is configured in a separate housing, shown in FIG. As described above, it is possible to assemble them and use them together. 2g 'is print paper.

Data exchange between the data carrier 1 and the handy terminal 2 will be described below with reference to FIGS. 1 and 4. First, the tip of the data read / write unit 2 ₃ is brought close to the data carrier 1 and the read key of the handy terminal 2 is turned on. As a result, in the handy terminal 2, the oscillator 2b sends a predetermined oscillation frequency to the antenna coil 2a under the control of the controller 2e. The antenna coil 2a receives this and generates magnetic energy, and this magnetic energy is emitted to the antenna coil 1e of the data carrier 1. The antenna coil 1e of the data carrier 1 converts this magnetic energy into a current and sends it to the power supply unit 1f. In response to this, the power supply unit 1f supplies necessary electric power to the control unit 1b and other parts of the apparatus. As described above, the data carrier 1 can be operated without a battery inside, and therefore maintenance such as battery replacement is unnecessary. This means that data storage / attachment to a gas container that is not rarely left in the distribution process for a fairly long period of time.
This is an excellent aspect of the data carrier 1 as a transmission medium. The control unit 1b receives the supply of electric power from the power supply unit 1f to start operation, and commands the memory 1a to read data.
Based on the read command, the memory 1a sends the gas container management data to the serial / parallel data conversion unit 1c according to the stored program. The serial / parallel data conversion unit 1c converts the parallel data received from the memory 1a into serial data, and the conversion / demodulation unit 1d
Send to. The modulation / demodulation unit 1d converts the received data to a high frequency in the radio frequency band, for example, the FSK method or A
A known data transmission wave such as the SK method is superimposed and modulated, and is sent to the antenna coil 1e. This causes the antenna coil 1e to oscillate and send out a signal wave. The antenna coil 2a of the handy terminal 2 receives this and sends this signal wave to the demodulation section 2c to demodulate the data. Further, under the control of the control unit 2e, the serial / parallel data conversion unit 2d converts the parallel data into the memory 2f.
And is stored as read data of the data carrier 1. At the same time, the read data is displayed on the display unit 2 ₂ .

For writing data to the data carrier 1 using the handy terminal 2, first, the tip of the data reading / writing section 2 ₃ is brought close to the data carrier 1 and the write key of the handy terminal 2 is turned on. Read the data stored in 1. Since the display unit 2 ₂ displays the read data, the cursor key is operated to position the cursor at the beginning of the data to be written or rewritten. For example, when rewriting the store number, the store number “0000321” read and displayed (see FIG. 5)
Position the cursor at the beginning of the data and input "0000322" with the number keys to overwrite this data. After confirming this input data, set the tip of the data reading / writing section 2 ₃ to the data carrier 1
And turn on the write key. At the same time as this ON operation, the transmitter 2b oscillates, so that the antenna coil 2
Power supply energy is sent from the a to the data carrier 1 to start the operation of the data carrier 1 as described above. When the write key is turned on, the input data is converted into serial data by the serial / parallel data conversion unit via the memory 2f based on the control of the control unit 2e, and further the modulation / demodulation unit 2c converts the radio frequency. A signal wave is superimposed on the high frequency of the band and sent to the antenna coil 2 a and sent to the data carrier 1. In the data carrier 1, this transmitted data is received by the antenna coil 1e and demodulated by the modulation / demodulation unit, and the demodulated signal is parallel / serial conversion unit 1
Parallel conversion is performed by c. Then, under the control of the control unit 1b, the data is written in the corresponding portion of the memory 1a. In this way, the data writing of the data carrier 1 is performed using the handy terminal 2.

Next, the actual use will be described. First, data is set in the data carrier 1. This data is set by the host computer 3 of the data processing device 3.
This is performed by the dedicated data writer 3b which has received the data transfer from a. The data written here are the gas container number, the date of manufacture of the container, the type of gas, the maximum weight, the distributor number to which the gas is delivered, and the like. As shown in FIGS. 2 and 3, a steel band 4 is inserted into a through hole 1 ′ formed in the data carrier 1 as shown in FIGS. 2 and 3, and the steel band 4 is used by the steel band. The valve portion 5'of the container 5 is wound and attached. In this way, the data carrier 1 is attached,
Gas is filled and preparation for shipment is completed. Upon delivery, the delivery person has a delivery slip printed out by the printer 3c of the host computer 3a in advance,
The handy terminal 2 may be used to check whether or not there is an error by collating with the read data of the data carrier 1 attached to the gas container to be delivered. Also, after receiving the transfer of the gas container management data to be delivered from the host computer 3a and storing this data in the memory 2f of the handy terminal, the data of the data carrier 1 of the gas container is read and the data of the gas container not to be delivered is stored. When the data of the data carrier 1 is read, a display to that effect may be displayed on the display unit 2 ₂ of the handy terminal 2. After such work, it is shipped from the filling factory.

When the delivery person unloads the product from the store and then pulls up the empty gas container, as described above, the data in the data carrier 1 of this gas container is read by the handy terminal 2 and the read data is read. Are stored in the memory 2f. Then, the printer 2g connected to the handy terminal 2 issues a temporary receipt indicating that the gas container has been collected. FIG. 5 shows the format of the gas container provisional receipt printed on the print paper 2g '. Input date is input by the input keys 2 ₁ numeric key of the handy terminal 2, is printed out in accordance with a built-in program by the print key to ON. The fact that the gas container temporary receipt has been issued is also stored in the memory 2f of the handy terminal 2. By performing this operation at each store, the data of the collected gas containers are sequentially accumulated in the memory 2f of the handy terminal 2.

In the filling factory, the data stored in the memory 2f of the handy terminal 2 is transferred to the host computer 3a. That is, the connection cord 2k ₁ is inserted into the connection cord insertion port 2 ₄ of the handy terminal 2, the other end of the connection cord 2k ₁ is connected to the data processing device 3, and the data stored in the handy terminal 2 is stored in the host computer 3a. To transfer. The host computer 3a, which has received this data transfer, automatically manages the gas container by processing the data of the gas container collected according to a predetermined program.

The handy terminal 2 is used to write data in the data carrier 1 in the following cases, for example. That is, there is a case where an unused gas container remains at a certain store even on the collection day of the gas container, and it becomes necessary to deliver an unscheduled gas container to a certain store. In such a case, the store number stored in the data carrier 1 of the recovered unused gas container is rewritten to the store number of the transfer destination. The rewriting of this data has not been repeated since it has already been described in detail, but the fact of rewriting this store number is also stored in the memory 2f of the handy terminal 2 and sent to the host computer 3a as described above.
Alternatively, an unregistered gas container may be in circulation in addition to the registered gas container. When a person in charge of delivery finds such a gas container at the delivery destination, it sets the data on the data carrier on hand and attaches it to the gas container to distribute it as a registered gas container. You can

As described above, the data processing device 3 manages the gas containers in the filling factory. First, the host computer 3a uses the container numbers and container numbers based on the unique numbers of the respective gas containers. Basic data such as the date of manufacture, the type of gas to be filled, the maximum weight, the date of filling, the name of the store to which the product is to be delivered, the number of the store, the date of shipment, and the date of collection are entered. Data carrier 1
When data is written to, the data to be written is sent to the data writer 3b based on the gas container number. Further, upon receiving the data transmission from the handy terminal 2 which has accumulated the collected gas container management data, the required processing such as recording the date of collection is automatically performed according to the control program. As described above, as one embodiment of the present invention, the data carrier 1 is capable of both writing and reading, but a read-only data carrier may be used depending on the mode of the system to be constructed.

[0019]

As described above, according to the present invention, the data of the data carrier in which the data is set in advance is read by the handy terminal as the data reading device, and the read data is transferred to the host computer of the data processing device. Since the gas container is managed or the data of the data carrier can be rewritten at the location such as a store by the handy terminal, it is not necessary to fill in a ledger by handwriting or input data with a keyboard. Or it will decrease significantly. As a result, it is possible to reduce the number of man-hours required for shipping and collecting the gas container. Further, since it is possible to prevent the management data from being confused due to an entry error or an input error, it is possible to surely confirm the location of the gas container and confirm the shipment and collection status. This can be easily done by the host computer of the processor. Therefore, it is possible to prevent the gas container from staying at a store for a long period of time, improve the circulation rate of the gas container, and eliminate the burden of keeping an extra inventory of the gas container at the filling factory. In addition, since data is transmitted and received between a data carrier as a data transmitter attached to a gas container and a handy terminal as a reading device for reading the data of this data carrier, wireless reading is performed without contact. There is an effect that contact failure does not occur during reading.

[Brief description of drawings]

FIG. 1 is a system configuration diagram of the present invention. This figure is drawn horizontally.

FIG. 2 is an external view of a data carrier.

FIG. 3 is an external view of a state in which the data carrier is attached to a gas container.

FIG. 4 is an external view of a handy terminal. This figure is drawn horizontally.

FIG. 5 is a printout format of a gas container temporary receipt.

[Explanation of symbols]

 1. Data carrier 1a, memory 1b, controller 1e, antenna coil. 1f / power supply unit 2 / handy terminal 2a / antenna coil 2b / oscillation unit 2e / control unit 2f / memory 2g / printer 2i / power supply unit (battery) 2j / interface 2k / connection code 3 / data processing device 3a / host Computer 3b · Data writer 4 · · Steel band 5 · · Gas container

Claims (4)

[Claims] 1. A gas container management data is set in a data transmitter, the data transmitter in which the gas container management data is set is attached to a gas container, and the gas container management data transmitted by the data transmitter is set as a data relay device. Gas container management, wherein the gas container management data read by the data relay device is transferred to the data processing device, and the data processing device receives the transfer of the gas container management data to perform data processing. Method. 2. A data transmitter having a memory for storing gas container management data and a transmitter for transmitting data set in the memory, a reader and data for reading the data transmitted by the data transmitter. A data relay device having a memory for storing the data, and a data processing device for receiving the gas container management data read by the data relay device and performing data processing, wherein the data transmitter is attached to a gas container. A gas container management system characterized by being used. 3. The gas container management system according to claim 2, wherein the data transmitter has a data receiving unit, and the data relay device has a data writing unit to the data transmitter. 4. The gas container management system according to claim 2, wherein the data transmission and reception between the data transmitter and the data relay device are performed using radio in a radio frequency band.