DE20116268U1 - Gas cylinder monitoring system for firemen has wireless data and power link - Google Patents

Abstract

A gas cylinder (10) monitoring system uses a transponder with wireless data link to a fixed transmit receive unit (12) and contactless alternating field power supply (40) from that unit to transmit pressure and wall temperature data.

Description

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drying. Ernst Stratmann

Patent Attorney
d-40212 düsseldorf · schadowplatz 9

24 September 2001

0119Gm

Frank Scheuermann
45739 Oer-Erkenschwick

Siegfried Schulze
47495 Rheinberg

Arrangement for contactless monitoring of compressed gas containers

The invention relates to an arrangement for the contactless monitoring of compressed gas containers, comprising a stationary transmitting and receiving unit with a transmitting and receiving antenna, past which compressed gas containers provided with a transponder unit can be guided in such a way that the transponder unit is supplied with energy by the stationary transmitting and receiving unit and data can be exchanged between the two units.

A method for recording the circulation (such as filling, emptying, transport, storage) of barrels is already known from WO 96/20459, in which method a transponder attached in or on the barrel is initially in operative connection with a transmitting and receiving device assigned to the filling station for the purpose of transmitting data during the filling of the barrel at the filling station, whereby during or after the filling of the barrel, filling data such as the filling date, an identifier relating to the type of liquid filled, the filling quantity, a running filling number, etc. are transmitted from the transmitting and receiving device to the transponder and stored there as a data set in such a way that it can be retrieved in such a way that it can then be read out and/or updated at a later point in time at another location.

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WO 00/50866 discloses a device for measuring pressures, temperatures, pulses, expansions and other values in and of hose lines during operation, in which at least one measuring unit is arranged in the hose line or on its wall, which is firmly connected to the wall. The device also includes at least one sensor for each measured value, a transponder and an antenna for wireless data transmission of the measured values to an external evaluation unit.

Finally, reference should be made to DE 200 00 609 U1, from which an electronic identification of respiratory protection devices is known, in particular a device for holding a transponder that is used for the electronic identification of respiratory protection devices for the self-rescue of miners. It is shown that with the help of transponders attached to the housings of the self-rescuers, it is possible to assign an unchangeable identification number to the transponder and thus to the self-rescuer. So-called read-write transponders also have, in addition to this unchangeable identification number, a free memory area where user-specific information can be stored. Both the identification number and this user-specific data can be updated at any time using suitable read/write units and re-written into the transponder.

Compressed gas containers filled with oxygen are preferably used for breathing apparatus in such self-rescue facilities. Firefighters also use breathing apparatus containing oxygen cylinders for fires where they often have to enter smoke-filled rooms. The problem here is that the contents of the oxygen cylinder and thus the time for which oxygen is available should always be monitored so that the oxygen does not run out during the firefighting operation and the firefighter suffocates. Another problem with firefighting is overheating, which can lead to a disruption of the oxygen supply.

The object of the invention is to ensure that, in an arrangement of the type mentioned at the outset, such disturbances do not occur or no longer occur to the same extent as was previously the case.

The object is achieved in that the transponder unit comprises sensors for physical data of the compressed gas container, such as wall temperature and gas pressure in the compressed gas container, which are connected to a microprocessor which records the sensor data and which in turn is connected to a mobile transmitting and receiving unit connected to a transmitting and receiving antenna and a power supply in such a way that the physical data can be transmitted to the stationary transmitting and receiving unit.

In this way, for example, the pressure of the contents in the oxygen cylinder can be monitored, and thus the oxygen supply still available. Furthermore, the temperature of the cylinder wall can also be monitored, so that the danger of explosion due to overheating of the oxygen cylinder can be detected in good time. At the same time, the arrangement also serves to identify the compressed gas cylinder and thus, if necessary, the fireman or miner who carries this compressed gas cylinder in a rescue unit or otherwise.

The power supply is preferably provided by a battery. This can conveniently be a rechargeable battery, in which case it is advantageous to provide a charging circuit connected to the battery, which is coupled to the receiving antenna of the mobile transmitting and receiving device or another receiving device. This enables contactless charging of the battery. The transponder can be attached to the compressed gas container in a known manner, for example by means of a mechanical clip device or by gluing, preferably to a protected area, such as in the case of a compressed gas container in the form of a gas bottle with a protective floor border within the protective floor border on the floor. The transponder itself will be designed as a component that is as robust as possible, for example as a circuit board with

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Epoxy resin coating, more generally a plastic-coated component from which only connections for sensors lead out so that the sensors can be connected or are connected.

It is advantageous if the transponder unit has a special signal output for controlling signal or alarm devices. If necessary, for example if the pressure in the oxygen bottle drops too much, the person carrying it, such as a fireman or miner, can be alerted to the danger of a lack of oxygen by means of an LED or a warning siren. The signal can also be used to make it easier to find the monitoring device and thus the person connected to it.

The times when the device is not being used are favorable for recharging the battery, so it is advantageous if the charging device comprises a charging cradle in which the compressed gas container, such as a gas bottle, can be set or inserted in such a way that the antenna or coil of the charging device is coupled to an alternating field which emanates from the charging cradle or a coil arranged therein.

The invention is explained in more detail below using embodiments shown in the drawings.

It shows:
Fig.1

schematic of the stationary transmitting and receiving unit and a mobile transmitting and receiving unit arranged on a compressed gas container that can be detected by it; and

Fig. 2 shows the lower end of the pressure gas container with the

The mobile transmitting and receiving unit is shown in more detail.

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In Fig. 1, an arrangement for contactless monitoring of compressed gas containers 10 can be seen, consisting of a stationary transmitting and receiving unit 12 and a transmitting and receiving antenna 14, past which the compressed gas container 10 provided with a transponder unit 16 can be guided in such a way that the transponder unit is supplied with energy by the stationary transmitting and receiving unit 12 or by a special switching device such as a charging cradle 18 and data can be exchanged between the two units 12, 16, see the double arrow 20.

The transponder unit 16 shown enlarged and schematically in Fig. 2 comprises or is connected to sensors 22, 24 for data of the compressed gas container, such as the temperature of the gas inside the compressed gas container or the temperature of its bottom wall 26, the gas pressure in the compressed gas container, the type of gas, etc., which sensors 22, 24 are connected to a microprocessor 28 which records the sensor data. The microprocessor 28 is in turn linked to a mobile transmitting and receiving unit 32 connected to a transmitting and receiving antenna 30 and a power supply 34, such that the physical data can be transmitted to the stationary transmitting and receiving unit 12. The energy supply 34 can comprise a battery 36, which may be replaceable, or rechargeable, so that it can be recharged via a charging circuit within the energy supply 34, which charging circuit in turn receives its energy either via the receiving antenna 30 of the mobile transmitting and receiving device 16 when this is located in the vicinity of the stationary transmitting and receiving device 12, or, even more advantageously, is coupled to its own coil or antenna 38, which receives its energy from a charging cradle 18, in which the compressed gas container 10 can be set or inserted in such a way that the antenna or coil 38 of the charging device is coupled to an alternating field 40 which emanates from the charging cradle or a coil 42 arranged therein.

In order to be prepared for the harsh environmental influences of a gas cylinder,

It is advantageous if the transponder unit 16 is designed as a component encased in plastic 44, for example as a circuit board with the components 28, 32, 34, 36, 38, which is encased in epoxy resin. Lines or connection devices 46, 48 can then extend from this plastic encapsulation in order to connect the sensors 22, 24, which are located, for example, inside the gas container and are guided through the base wall 25.

The gas cylinder 10 shown here is one with a protective base 50, so that a space is created in which the transponder unit 16 can be arranged close to the base 26 of the gas cylinder, protected by the base 50. In the embodiment shown here, the transponder unit 16 has a special signal output 52 for controlling signal or alarm devices which, for example, emit a visual or acoustic warning signal when a certain gas pressure is undershot. The person carrying the gas cylinder, a fireman or miner, is then warned that they must replace their gas cylinder within a certain period of time.

This warning can of course also be transmitted via the transponder device to the stationary transmitting and receiving unit 12 and from there to a control center, which could initiate the rescue measure.

Conveniently, the charging cradle also serves to accommodate the compressed gas container when not in use, so that the time of non-use can be used to charge a rechargeable battery by the charging device with the alternating field 40.

Claims (17)

1. Arrangement for contactless monitoring of compressed gas containers ( 10 ), comprising a stationary transmitting and receiving unit ( 12 ) with a transmitting and receiving antenna ( 14 ), past which compressed gas containers ( 10 ) provided with a transponder unit can be guided in such a way that the transponder unit ( 16 ) is supplied with energy by the stationary transmitting and receiving unit ( 12 ) and data ( 20 ) can be exchanged between the two units ( 12 , 16 ), characterized in that the transponder unit ( 16 ) comprises sensors ( 22 , 24 ) for physical data of the compressed gas container ( 10 ), such as wall temperature of the and gas pressure in the compressed gas container ( 10 ), which are connected ( 46 , 48 ) to a microprocessor ( 28 ) which records the sensor data, which microprocessor ( 28 ) in turn is connected to a is connected to a mobile transmitting and receiving unit ( 32 ) connected to a transmitting and receiving antenna ( 30 ) and a power supply ( 34 ) in such a way that the physical data can be transmitted to the stationary transmitting and receiving unit ( 12 ). 2. Arrangement according to claim 1, characterized in that the energy supply ( 34 ) comprises a battery ( 36 ). 3. Arrangement according to claim 2, characterized in that the energy supply ( 34 ) comprises a charging circuit ( 34 , 38 , 40 , 14 ) connected to the battery ( 36 ) which is coupled to the receiving antenna ( 30 ) of the mobile transmitting and receiving device ( 32 ) or to another receiving device, such as a coil ( 38 ). 4. Arrangement according to one of claims 1 to 3, characterized in that the transponder unit ( 16 ) is designed as a plastic-coated component, such as a circuit board with an epoxy resin coating, to which the sensors ( 22 , 24 ) can be connected or are connected. 5. Arrangement according to claims 1 to 4, characterized in that the compressed gas container ( 10 ) is a gas bottle with a floor protection border ( 50 ), and that the transponder unit ( 16 ) is arranged on the floor ( 26 ) near the floor border ( 50 ). 6. Arrangement according to one of claims 1 to 5, characterized in that the transponder unit ( 16 ) has a special signal output ( 52 ) for controlling signal or alarm devices. 7. Arrangement according to one of claims 1 to 6, characterized in that the charging device comprises a charging cradle ( 18 ) in which the compressed gas container ( 10 ), such as a gas bottle, can be set or inserted in such a way that the antenna ( 30 ; 38 ) or coil of the charging device ( 34 ) is coupled to an alternating field (e.g. 40 or 20) which emanates from the charging cradle ( 18 ) or a coil ( 42 ) arranged therein. 8. Arrangement according to one of claims 1 to 7, characterized in that the pressurized gas container is an oxygen bottle for firefighters. 9. Arrangement according to one of claims 1 to 7, characterized in that the pressurized gas container is an oxygen bottle for the self-rescuer of miners. 10. Pressure gas container with non-contact monitoring, characterised by the following features: A) A (movable) transponder unit ( 16 ) is arranged on the pressure gas container ( 10 ) to be monitored, B) the compressed gas container ( 10 ) provided with the movable transponder unit ( 16 ) can be guided past a (stationary) transmitting and receiving unit ( 12 ) in such a way that C) that an exchange of data ( 20 ) between the two units ( 12 , 16 ) is made possible. 11. Pressure gas container according to claim 10, characterized by A) means for measuring physical data of the compressed gas container ( 10 ), such as wall temperature and gas pressure in the compressed gas container ( 10 ) by means of corresponding sensors ( 22 , 24 ); B) means for digitizing, processing and/or storing the data in a microprocessor ( 28 ); C) means for modulating the data onto an RF carrier in a mobile transmitting and receiving unit ( 32 ) and feeding it into an antenna coil ( 30 ). 12. Pressure gas container according to claim 11, characterized by A) (stationary) devices which can be linked to the compressed gas container for receiving the RF carrier ( 20 ) by means of a transmitting and receiving antenna ( 14 ) of the stationary transmitting and receiving unit ( 12 ); and B) means for demodulating and processing the RF signals and storing, forwarding and/or displaying the data on a display ( 52 ). 13. Pressure gas container according to claim 10, 11 or 12, characterized by A) means for entering control data for the transponder ( 28 ) of the compressed gas container ( 10 ), such as identification data, type of treatment, type of gas, etc., by means of a keyboard ( 54 ) or the like; B) means for digitizing, processing and/or storing the data in a microprocessor ( 28 ); and C) Means for modulating the data onto an RF carrier in a transmitting and receiving unit and feeding it into an antenna coil. 14. Pressure gas container according to claim 13, characterized by A) means for receiving the RF carrier signal ( 20 ) by means of a mobile transmitting and receiving antenna ( 30 ); and B) Means for demodulating and processing the RF signals and storing them in the transponder unit. 15. Pressure gas container according to claim 14, characterized by A) Devices for transmitting and/or displaying the data by means of a display, a warning lamp, a warning tone. 16. Pressure gas container according to one of claims 11 to 15, characterized by A) a charging device in the transponder unit with a downstream energy storage device ( 36 ) for supplying the transponder unit ( 16 ). 17. Pressure gas container according to claim 16, characterized by A) a charging device ( 34 , 38 ) and means for arranging the charging device ( 34 , 38 ) near an alternating electric field ( 40 ) for contactless transmission of electrical energy into the charging device ( 34 , 38 ).