DE202016003193U1 - explosion protection - Google Patents

Abstract

An explosion protection system comprising: a suction pump (3) that draws in ambient air via a pipe (L1); a gas analysis and evaluation unit (4), which is connected to the suction pump (3) and is provided by this with sample gas; at least one inert gas source (2); a valve (5), wherein the valve (5) is connected on one side to the inert gas source (2), on the other side with a nozzle (6), so that gas from the inert gas source (2) through the nozzle (6 ), wherein the gas analysis and evaluation unit (4) controls the opening state of the valve (5).

Description

The present invention relates to an explosion protection system for use in ATMs, pay machines and other technical devices in which cash is stored, collected or dispensed.

The press has recently been receiving more and more reports of "blowing-up" of ATMs at banks, savings banks and markets by introducing explosive gases or substances into an area of these machines and the subsequent ignition of the explosive mixture. This often leads not only to severe damage or total destruction of the ATM, but also to the destruction of the environment or z. B. the ticket hall. If there are people nearby, serious personal injury is also possible.

Due to these developments, there is a need for corresponding security concepts that can be adapted for different individual environmental situations.

It is therefore an object of the present invention to provide an explosion protection system for ATMs, pay machines and other cash-saving machines available, in which after the introduction of combustible gases / substances in the machine, which can form explosive mixtures, an explosion can be avoided. Main aspect here is the primary explosion protection, d. H. the prevention of the formation and spread of explosive atmospheres. Furthermore, in the determination of the introduction of a flammable or explosive gas mixture also issued an alarm and / or z. B. video recording devices or image recording devices can be started.

This object is achieved by an explosion protection system having the features according to claim 1, as well as a use in ATMs according to claim 11. Further advantageous embodiments of the invention are the subject of the dependent claims.

The invention includes an explosion protection system in which the preventive explosion protection is divided into three areas: First, a detection of combustible substances / gases, which can form explosive mixtures, by means of suitable devices. The detection can z. B. at an ATM near the cash dispensing shaft. Furthermore, the system provides for a substitution of the explosive atmosphere by an inert gas, so that no more explosive atmosphere is present. Furthermore, the explosion protection system also provides alarm triggering, which may be of various types, such as the connection to an existing fire alarm system and / or but optical / acoustic signalers, video / image recording devices and SMS / mail modules.

In the following, a preferred embodiment will be explained in more detail with reference to the accompanying drawings.

1 is a schematic representation of an explosion protection system or a circuit diagram.

2 shows a schematic exploded diagram of any ternary substance mixture consisting of inert gas, oxidizer and fuel gas.

First embodiment

1 shows a circuit diagram of an explosion protection system in one embodiment. Here, the explosion protection system in conjunction with an ATM 1 used, which is to be protected. Main components of the explosion protection system are inert gas containers 2 , which are designed in the present embodiment as a pressure vessel, a suction pump 3 , a gas analysis and evaluation unit 4 , an electromagnetic valve 5 and a nozzle 6 ,

In the immediate vicinity of the cash dispenser slot G of the ATM 1 the end of a line L1 is provided, which at the other end with the suction pump 3 connected is. The line L1 is formed as a flexible hose, which has a diameter of 3-10 mm, preferably 8 mm. The hose length is 2-20 m, preferably 4-8 m, more preferably 5 m. Thus, the suction pump 3 suitable for sucking in ambient air at the cash dispensing shaft G. The suction pump 3 is mounted outside the machine in the present embodiment. The suction pump 3 is set so that the intake of the ambient air is continuous. The ambient air is passed through a further line L2 to the gas analysis and evaluation unit 4 passed. The gas analysis and evaluation unit 4 analyzes the sample gas flow coming from the suction pump 3 sucked in, also steady. The gas analysis and evaluation unit 4 consists in the present embodiment of various calibrated measuring sensors, which are each capable of detecting flammable substances or gases and their concentration. The combustibles and gases in the present embodiment include benzene, n-butane, iso-butane, 1-butoxy-2-propanol, cyclohexane, cyclopropane, ethane, ethene, ethyne, ethene oxide, hexane, carbon monoxide, methane, pentane, propane, Propene, propene oxide, gasoline (gasoline), hydrogen, heptane, toluene, xylene, Methyl ethyl ketone, ethanol, methanol, 1-propanol, 2-propanol, ethyl acetate, propyl formate, carbon disulfide, cyclohexanol, 1-hexanol, dipropyl ether, acetaldehyde, butanal, 1-butanol, t-butanol, cyclohexanone, butyl acetate, pentyl acetate, dipropylene glycol dimethyl ester, dimethyl ether, Hexamethyldisiloxane, 1,4-dioxane, tetrahydrofuran and acrylic acid. Furthermore, in the ambient air, the concentration of the oxidizer, in this case the oxygen concentration, is continuously measured by a calibrated sensor.

The gas analysis and evaluation unit 4 So is able to do that through the suction pump 3 sucked sample gas to analyze both qualitatively and quantitatively.

In the gas analysis and evaluation unit 4 Furthermore, the oxygen limit concentrations for each of these combustible or explosive substances are deposited.

The gas analysis and evaluation unit 4 is able to send signals to the valve 5 pass on, as to an alarm 7 , which can output a visual and / or acoustic signal, as well as a signal generator 8th for connecting to any existing fire alarm systems. Such signals are output when the gas analysis and evaluation unit 4 detected a combustible substance in a specified minimum concentration.

The valve 5 is formed in the present embodiment as an electromagnetic valve and via a line L3 with the inert gas source 2 connected. On the other side is the valve 5 via the line L4 with the nozzle 6 connected, which is formed in the present embodiment as a spray nozzle. This spray nozzle 6 is inside the ATM 1 provided, in the present case in the immediate vicinity of the cash dispensing shaft G, ie at a location where a high local concentration of combustible substances is possible or likely. Thus, with appropriate opening of the valve 5 Inert gas from the inert gas source 2 to the spray nozzle 6 flow, and from there to the immediate vicinity of the spray nozzle 6 to locally substitute the oxygen in the air with an inert gas, which leads to a decrease in the local oxygen concentration (and by dilution also to a decrease in the concentration of the combustible substance), until an oxygen limit concentration is reached at which an explosion becomes impossible. This oxygen limit concentration is different for each combustible substance. There is so much inert gas through the spray nozzle 6 output until an oxygen limit concentration of a certain combustible or explosive substance is reached or fallen below again. The continuous measurement of the local oxygen concentration by the gas analysis and evaluation unit 4 allows a precise determination of this time.

Suitable inert gases are CO ₂ , nitrogen and the noble gases. The appropriate inert gas must be selected according to the environmental variables of the environment in which the ATM is located 1 stands.

In the present embodiment is near the ATM 1 an alarm device 7 appropriate. This emits an acoustic and / or optical signal, such as a loud beep and / or a flashing or flashing light. Furthermore, within the system is a signal generator 8th arranged, which can be connected to any existing fire alarm or alarm systems.

With the help of 2 Now, the operations performed in the explosion-proof system of the present embodiment will be explained.

The state in which there is an increased concentration of a combustible or explosive gas is in 2 marked with A. It is located between the upper explosive limit (OEG) and the lower explosive limit (LEL). After opening the valve 5 inert gas flows through the nozzle 6 from what is in the immediate vicinity of the nozzle 6 First, dilute the explosive gas mixture, and second, displace the atmospheric oxygen with inert gas (indicated by B). Thus, a gas mixture with a lower concentration of fuel gas and oxidizer (in the present case oxygen) is formed in comparison to point A, but with a higher inert gas concentration. The valve remains open until an oxygen limit concentration is reached at which no more explosive mixtures can arise. For safety reasons, it is also possible to set a specific value by which the oxygen limit concentration must be fallen below until the valve 5 closed again. The present invention is not limited to the embodiment described above. The gas analysis and evaluation unit 4 For example, it can contain several gas sensors, which are designed as chemosensors. In this case, the chemical information of the ambient air from the gas sensor is converted into an electrically usable signal. There are many possibilities of gas detection, which differ according to the way in which the chemical information is converted into electrical or electronic signals. Each gas sensor in this case must be calibrated to a specific gas, also to a certain concentration range. It must therefore be stipulated at which concentration ranges of combustible or explosive substances there is a risk of explosion.

Among other things, physical measuring methods that exploit the molecular properties of individual molecules for detection are used as measuring methods in gas sensors. In this case, for example, the molecular mass, the diffusion behavior, the molecular structure, the magnetic properties or paramagnetism, the molecular stability or binding energy and the molecular mobility can be measured.

Furthermore, chemical measuring methods are used which exploit chemical properties of certain molecules, for example reactivity, oxidizability and reducibility.

Also suitable are, for example, sensors which measure the conductivity of the gas or gas mixture to be measured. For example, metal oxide semiconductors, conductive polymers or solid-state ion conductors (lambda probes) are suitable here.

Furthermore, amperometric sensors are possible, for example electrochemical cells, flame ionization detectors or photoionization detectors. Thermal conductivity detectors are also frequently used.

Furthermore, the gas analysis and evaluation could 4 also be designed as a mass spectrometer (MS). A mass spectrometer is capable of ionizing the substance to be assayed, thereby forming a characteristic fragmentation pattern for a particular substance. The use of a mass spectrometer has the advantage that with a device a large number of gases can be detected, since the magnetic or electric fields in the mass spectrometer, which deflect corresponding ions or fragments, can change continuously in a short time, so that, for example, per second a variety of different ions or fragments can be analyzed. A method using a mass spectrometer enables on-line gas analysis, which can determine the concentration of several substances in a short time.

The alarm device 7 can output further signals in addition to optical acoustic signals:
For example, a silent alarm, z. B. by an SMS or e-mail module possible. Furthermore, camera records, possibly with ring buffer, can be triggered.

Furthermore, the explosion protection system can be realized in a control cabinet, which can be placed for example next to the ATM. Furthermore, the system could also be implemented externally, for example above the ATM, in a false ceiling.

The line L1 can also be designed as a fine capillary, with a diameter of less than 0.1 mm.

Also conceivable would be several lines L1, which end not only in the vicinity of the cash dispensing shaft, but also, for example, in other positions within the ATM 1 , in which also easily combustible gas could be introduced.

The present invention includes an explosion protection system for, for example, ATMs, being at a certain position in the ATM 1 constantly ambient air is sucked in. This is done by a gas analysis and evaluation unit 4 analyzes which on detection of a combustible substance, the opening of an example electromagnetic valve 5 which controls the flow of inert gas from an inert gas source 2 to a spray nozzle 6 allows, for example, in the vicinity of the cash dispensing slot G of the ATM 1 is mounted and allows inert gas to flow out and thus lowers the local oxygen concentration and the concentration of the combustible substance by displacing atmospheric oxygen and combustible substance by inert gas. This lowers the oxygen limit concentration necessary for an explosion to destroy the explosive atmosphere.

Claims (11)

Explosion protection system comprising: a suction pump ( 3 ), which draws in ambient air via a line (L1); a gas analysis and evaluation unit ( 4 ), which with the suction pump ( 3 ) and is provided by this with sample gas; at least one inert gas source ( 2 ); a valve ( 5 ), whereby the valve ( 5 ) on one side with the inert gas source ( 2 ), on the other side with a nozzle ( 6 ), so that gas from the inert gas source ( 2 ) through the nozzle ( 6 ), whereby the gas analysis and evaluation unit ( 4 ) the opening state of the valve ( 5 ) controls. Explosion protection system according to claim 1, wherein the gas analysis and evaluation unit ( 4 ) is designed so that it detects flammable substances and oxidizing substances qualitatively and quantitatively. Explosion protection system according to one of the preceding claims, wherein the line L1 has a diameter of 3-10 mm, preferably 8 mm has, and 2-20 m, preferably 4-8 m, more preferably 5 m long. Explosion protection system according to one of the preceding claims, wherein the nozzle ( 6 ) is designed as a spray nozzle and is preferably mounted in a place where a high local concentration of combustible substances is possible. Explosion protection system according to one of the preceding claims, wherein the inert gas source ( 2 ) is designed as a pressure vessel. Explosion protection system according to one of the preceding claims, wherein the valve ( 5 ) is designed as an electromagnetic valve. Explosion protection system according to one of the preceding claims, wherein the gas analysis and evaluation unit ( 4 ) additionally with an alarm transmitter ( 7 ), which outputs an audible and / or visual warning signal. Explosion protection system according to one of the preceding claims, wherein the gas analysis and evaluation unit ( 4 ) additionally with a signal generator ( 8th ) is connected for connection to existing fire alarm and / or alarm systems. Explosion protection system according to one of the preceding claims, wherein the gas analysis and evaluation unit ( 4 ) comprises one or more gas sensors. Explosion protection system according to one of claims 1-8, wherein the gas analysis and evaluation unit ( 4 ) comprises a mass spectrometer. Use of an explosion protection system according to one of claims 1-10 in an ATM ( 1 ), whereby the suction pump ( 3 ) constantly draws air from the vicinity of the cash dispensing shaft, and the nozzle ( 6 ) is located near the cash dispenser (G).

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