CN215180157U - Device for realizing wave absorption and energy absorption of porous metal copper mesh in gas/air premixed gas deflagration experiment - Google Patents

Abstract

The utility model discloses a device of metallic copper net porous structure wave absorption energy in realizing gas/air premixed gas deflagration experiment. The system comprises an explosion shock tube, an out-of-tank premixed gas supply system, a pressure signal acquisition system, a flame signal acquisition system, a Donghua data acquisition system, a high-pressure ignition system and a synchronous control system; the explosion shock tube comprises a plurality of experimental pipelines and 1 visual observation window experimental section pipeline which are connected end to end; the tail end of the explosion shock tube is provided with a metal copper mesh porous structure; the synchronous control system is used for synchronously controlling the flame signal acquisition system, the pressure signal acquisition system, the Donghua data acquisition system and the high-pressure ignition system. The utility model discloses place the device of metal copper mesh porous structure wave absorption energy in the gas/air mixes gas deflagration experiment in advance, reduce casualties and loss of property.

Description

Device for realizing wave absorption and energy absorption of porous metal copper mesh in gas/air premixed gas deflagration experiment

Technical Field

The utility model relates to a device of metal copper mesh porous structure wave absorption energy-absorbing in realizing gas/air mixes gas deflagration experiment in advance belongs to safe science and technical field.

Background

In the coal mining process, gas is gas gushed from coal rocks, the main component is methane, when the gas is gathered to a certain concentration, the gas can explode when meeting an ignition source, coal mine accidents are caused, and great damage and damage are caused to underground personnel and equipment of a mine. At present, the development of novel energy is more and more emphasized, but coal still occupies a large proportion, and accounts for 70% -75% of the primary energy production and consumption structure. Although the mechanization degree of coal is higher and higher, large-scale comprehensive equipment is adopted for mining, with the increase of mining depth and the increase of high gas mines, gas explosion accidents are still prominent, and the problem is a leading-edge problem which needs to be researched urgently in the field of coal mine safety.

When the gas/air premixed gas is subjected to deflagration, the premixed gas is instantly converted into high-temperature and high-pressure explosion products and rapidly expands, so that the pressure and the density are reduced to form rarefaction waves, and the explosion products rapidly expand to compress the air in a roadway to form explosion shock waves. After the explosion shock wave is formed, the explosion shock wave is separated from explosion products, independently spreads in the air, and collides with a wall surface when meeting obstacles in a roadway to generate reflection, transmission and diffraction phenomena. Since the reflection phenomenon in the gas/air premixed gas detonation is a complex process, the multiple reflection process is not analyzed, and only the destructive property of the initial shock wave and the first reflection is analyzed. If the shock wave collides with a smooth rigid plane, the whole capacity can be reflected on the plane, and meanwhile, the overpressure of the reflected wave is multiplied by 2-8 times that of the incident wave. Meanwhile, because the coal mine tunnel is a closed space, the propagation of the shock wave in the tunnel is obviously different from the open-air propagation, and when the coal mine tunnel is positioned in the closed space of the tunnel, the attenuation rate of the shock wave is slower and the propagation distance is longer. At present, research shows that after shock waves are reflected by a fixed wall, overpressure of reflected waves is increased by multiple, and the shock waves are important reasons for increasing casualties and property loss in mine gas explosion accidents. Therefore, the research on the effect of wave absorption and energy absorption of one device has important engineering application value for further expanding the gas explosion accidents.

As can be seen from the literature, the study of the shock wave by scholars is more, most of the study is carried out by means of numerical simulation and model test, and remarkable results are obtained. The model test obtains a plurality of single point source information in a gas/air premixed gas deflagration flow field by means of a pressure and flame speed test system in a mode of building an experiment platform, and macroscopically analyzes the variation trend of a pressure peak value and the flame speed in a roadway from the angle of theoretical analysis so as to obtain the evolution process of a shock wave and the microstructure of flame in the deflagration process of the gas/air premixed gas. However, these studies have focused mainly on the destruction of the shock wave generated by the explosion, and there are few studies on the damage to personnel and the destruction of equipment by the reflected wave formed by the impact of the shock wave against the wall surface. Research shows that after the shock wave is reflected by the solid wall, the overpressure of the reflected wave is increased by multiple times, the reflected wave is more harmful than the incident wave, and the destructive effect is stronger than the incident wave, so that the research on the reflected wave and the wave absorption energy absorption needs to be strengthened.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a realize in gas air mixes gas deflagration experiment in advance that metal copper mesh porous structure wave absorption device of ability, the utility model discloses place in gas air mixes gas deflagration experiment in advance that metal copper mesh porous structure wave absorption device of ability reduces casualties and loss of property.

The utility model provides a device for realizing wave absorption and energy absorption of a metal copper mesh porous structure in a gas/air premixed gas deflagration experiment, which comprises an explosion shock tube, an out-tank premixed gas supply system, a pressure signal acquisition system, a flame signal acquisition system, a Donghua data acquisition system, a high-pressure ignition system and a synchronous control system;

the explosion shock tube comprises a plurality of experimental pipelines and 1 visual observation window experimental section pipeline which are connected end to end; the tail end of the explosion shock tube is provided with a metal copper mesh porous structure;

the tank outside premixed gas supply system is communicated with the inside of the explosion shock tube and is used for generating premixed gas with a preset equivalence ratio according to experimental requirements and inputting the premixed gas into the explosion shock tube;

the pressure signal acquisition system and the flame signal acquisition system are arranged on the side wall of each section of the experimental pipeline and are used for measuring the rule of the whole-course pressure and the flame propagation speed in the explosion shock wave pipe, and the measurement result is sent to the synchronous control system through the data acquisition system;

the Donghua data acquisition system is connected with the pressure signal acquisition system and the flame signal acquisition system and is used for acquiring and analyzing whole-course data in the explosion shock tube and acquiring and analyzing DHDAS dynamic signals;

the high-voltage ignition system is connected with the end part of the shock tube and is used for igniting the premixed gas in the shock tube;

the synchronous control system is used for synchronously controlling the flame signal acquisition system, the pressure signal acquisition system, the Donghua data acquisition system and the high-pressure ignition system;

the Donghua data acquisition system comprises a 16-channel data acquisition card and a DHDAS dynamic signal acquisition and analysis system.

In the device, the explosion shock tube is formed by connecting a plurality of sections of experimental pipelines connected end to end, 1 section of experimental section pipeline with a visual observation window and 3 sections of externally-added tubes connected end to end; the wall surface of an outer increase pipe at the tail end of the explosion shock tube is provided with a metal copper mesh porous structure;

the out-of-tank premixed gas supply system comprises a premixed tank system, a vacuum pumping system and a control cabinet system; the system comprises a premixing tank system, a methane gas cylinder and an air compressor, wherein the vacuumizing system comprises two connected vacuum pumps, and the control cabinet system comprises a first control cabinet and a second control cabinet which are connected; the premixing tank is connected with the methane gas cylinder, the air compressor and the vacuum pump through an air supply pipeline controlled by the first control cabinet, so that premixed gas in the premixing tank is input into the explosion shock tube connected with the premixing tank through the air supply pipeline; the vacuum pump is also connected with the explosion shock tube; the second control cabinet is connected with 3 air inlet ports on the explosion shock tube;

the pressure signal acquisition system comprises a plurality of piezoelectric pressure sensors; each piezoelectric pressure sensor is arranged on a plurality of experimental pipelines connected end to end, and transmits the acquired pressure signals to the Donghua data acquisition system through data lines;

the flame signal acquisition system comprises an optical fiber, an optical fiber sensor, a photoelectric integrator and a data acquisition system which are sequentially connected, is arranged on the end-to-end multi-section experimental pipelines, converts optical signals into electric signals and transmits the electric signals to the Donghua data acquisition system; the specific process is as follows: when flame light with gas/air premixed gas deflagration parameters reaches the position of the optical fiber sensor seat, an optical signal is transmitted into the optical fiber from a gap of the optical fiber sensor seat and then is guided into a photodiode (GT101) in the optical fiber sensor through the optical fiber, the current of the photodiode (GT101) is changed due to the change of the light, and the optical signal can be converted into an electric signal through the photoelectric integrator; inputting an electric signal into the data acquisition system, calculating a generated time difference according to the occurrence time of flame voltage signals of the optical fiber sensors at different acquired positions, and dividing the distance between the corresponding optical fiber sensors recorded when the optical fiber sensors are arranged by the time difference to obtain corresponding flame propagation speed;

the high-voltage ignition system comprises a capacitor and a diode, and is arranged at the foremost ends of a plurality of experimental pipelines which are connected end to end, the anode of the capacitor and the cathode of the diode are connected with a 220V power supply, the cathode of the capacitor and the anode of the diode are connected with a ground wire, the anode of the capacitor is used as the high-voltage anode of the high-voltage ignition system, the ground wire and the low-voltage anode output by the synchronous control system generate discharge, the low-voltage anode and the ground wire generate discharge, an air medium between the high-voltage anode and the ground wire is punctured, and gas/air premixed gas ignition is completed;

the synchronous control system is composed of a function signal generator, a time delayer and a solid-state relay, wherein an output port of the function signal generator is connected with an input port of the time delayer, output ports of the time delayer are respectively connected with the flame signal acquisition system, the pressure signal acquisition system, the Donghua data acquisition system and the solid-state relay, and an output port of the solid-state relay is connected with the high-pressure ignition system.

In the utility model, the position of the end in the 'metal copper mesh porous structure arranged at the end of the' explosion shock tube 'and the' end 'position in the' end of the 'explosion shock tube' refers to the position where the gas/air premixed gas detonates and finally passes through when passing through the section when the device is used;

the high-voltage ignition system comprises capacitors and diodes, and the position of the foremost end of the experiment pipelines which are connected end to end refers to the position where gas/air premixed gas passes through when deflagration passes through the section when the device is used.

In the device, the experimental pipelines are cold-drawn pipelines, and the cross sections of the experimental pipelines can be square, so that the coaxiality of the square cross-section pipelines is easy to guarantee, the cross-section area can be 200mm multiplied by 200mm, and the length of each section is 2500 mm;

the number of the experimental pipelines can be specifically 14, so that the length adjustment is convenient;

2 side surfaces and top surfaces of the same position on each section of the experimental pipeline are respectively provided with two hole seats for arranging a pressure sensor or a flame sensor;

k9 organic glass is arranged on the experimental section pipeline of the observation window and used for observing the flame change form; the length of the pipeline at the experimental section of the observation window can be 1000 mm;

the external pipe is a round steel pipe, the diameter of the cross section of the external pipe can be 300mm, and the length of each section can be 1200 mm;

all pipelines in the explosion shock tube are connected end to end by flanges, and the total length can be 38600 mm.

In the device, the premixing tank is connected with the first control cabinet through a ball valve and a high-pressure air pump line.

The 2 vacuum pumps are a first-stage pump rotary vane pump and a second-stage pump roots pump; the primary pump rotary vane pump and the secondary pump roots pump are communicated with the interior of the shock tube through high-pressure gas pump lines, and control ends of the primary pump rotary vane pump and the secondary pump roots pump are connected with the first control cabinet and the second control cabinet and are used for vacuumizing, charging and distributing the shock tube according to control signals of the first control cabinet and the second control cabinet;

and the output port of the first control cabinet is respectively connected with the air compressor, the methane gas cylinder and the second control cabinet and is used for respectively filling methane and air into the premixing tank according to a predetermined volume percentage according to a partial pressure law.

In the above device, the number of the piezoelectric pressure sensors may be 8 to 16;

and the piezoelectric pressure sensors are arranged on the plurality of experimental pipelines connected end to end at equal intervals.

In the above device, the software used by the DHDAS dynamic signal acquisition and analysis system can independently set different parameters, and is connected to the pressure signal acquisition system and the flame signal acquisition system.

The utility model also provides a method that foretell device realized in gas/air mixes gas deflagration experiment in advance metal copper mesh porous structure wave absorption energy-absorbing, including following step:

1) constructing the device for realizing wave absorption and energy absorption of the porous structure of the copper mesh in the gas/air premixed gas deflagration experiment;

2) the out-of-tank premixed gas supply system inputs premixed gas into the explosion shock tube; then, igniting through the high-voltage ignition system; measuring the whole-course pressure and flame propagation speed in the explosion shock tube by adopting the flame signal acquisition system and the pressure signal acquisition system to obtain measurement data;

3) transmitting the measurement data to the Donghua data acquisition system; and obtaining the wave absorption energy of the porous structure of the metal copper mesh in the gas/air premixed gas deflagration experiment through data analysis.

In the above-mentioned method, the data that metal copper net porous structure was not placed to specific accessible measurement explosion shock tube end, the data of metal copper net porous structure was placed to explosion shock tube end in the device of metal copper net porous structure wave absorption in the aforesaid realization gas/air premixed gas deflagration experiment, the above-mentioned 3 groups of data that metal copper net porous structure that length 350mm was placed to explosion shock tube end in the device of metal copper net porous structure wave absorption in the aforesaid realization gas/air premixed gas deflagration experiment are compared respectively, are analyzed, in order to prove the utility model discloses realize in gas/air premixed gas deflagration experiment that metal copper net porous structure wave absorption is placed.

The utility model has the advantages of it is following:

the utility model discloses the key gas/air that takes place often in the pit of solving the colliery mixes gaseous detonation accident in advance, nevertheless utilizes the explosion shock wave pipeline of current laboratory earlier to test, pastes the metal copper mesh and arranges in gas/air mixes gaseous detonation experimental system in advance. The explosion shock wave tube is a closed space, the tail end of the explosion shock wave tube is a rigid solid wall, when the explosion shock wave strikes the rigid solid wall, a reflected wave can be generated, the overpressure of the reflected wave is increased by multiple times and is several times of the overpressure of the shock wave: during weak explosion, the reflection pressure of gas and gas coal dust explosion is 1.8-2.0 times of the peak overpressure, the maximum overpressure of the gas coal dust explosion is obviously higher than that of the gas explosion, and the intensity of the reflection pressure is far higher than that of the gas explosion and is more destructive. And the reflection pressure of gas and gas coal dust explosion during strong explosion is 8-21 times of the peak overpressure. The presence of reflected waves further exacerbates the casualties and equipment property damage in the mine. Therefore, in order to prevent further expansion of gas explosion accidents, casualties and property loss are reduced. The metal copper mesh porous structure is reasonably designed and adhered to the tail end of the explosion shock tube to achieve the effect of wave absorption, and then the metal copper mesh is adhered to and arranged on the wall surface of a roadway under a coal mine to play the effect of wave absorption and energy absorption, so that gas/air premixed gas deflagration accidents frequently occurring under the coal mine are inhibited and reduced. The method has important engineering application value for reducing casualties and property loss in coal mine gas explosion accidents.

Drawings

Fig. 1 is the structure schematic diagram of the wave-absorbing energy-absorbing device with the porous structure of the metal copper mesh in the test system of the gas/air premixed deflagration experiment of the utility model.

Fig. 2 is the structural schematic diagram of the flame signal acquisition system in the middle gas/air premixed gas deflagration experimental test system of the utility model.

Fig. 3 is the metal copper mesh porous structure is not placed at the end of the explosion shock tube in the middle gas/air premixed gas deflagration experimental test system of the utility model.

Fig. 4 is a metal copper mesh porous structure with a length of 100mm placed at the end of an explosion shock tube in the middle gas/air premixed gas deflagration experimental test system of the utility model.

Fig. 5 is a metal copper mesh porous structure with a length of 350mm placed at the end of an explosion shock tube in the middle gas/air premixed gas deflagration experimental test system of the utility model.

Fig. 6 is the schematic layout of the pressure sensor and the flame sensor of the shock tube in the testing system for the deflagration experiment of premixed gas/air in the utility model.

Fig. 7 is a diagram showing a trend of the overpressure decay rate in embodiment 2 of the present invention.

The individual labels in the figure are as follows:

1, exploding a shock tube; 2, a premixed gas supply system outside the tank; 211 a premixing tank; 212 methane cylinders; 213 air compressor; 221 a vacuum pump; 231 a first control cabinet; 232 a second control cabinet; 3, a pressure signal acquisition system; 4, a flame signal acquisition system; 41 optical fiber sensor seat; 42 optical fibers; 43 a photodiode; a power supply 44; 45 resistance; 46 an oscilloscope; 5 Donghua data acquisition system; 6 high-pressure ignition system; 71 a function signal generator; a 72 time delay; 73 a solid state relay; 8, adding a pipe outside; 9 computer.

Detailed Description

The experimental procedures used in the following examples are all conventional procedures unless otherwise specified.

Materials, reagents and the like used in the following examples are commercially available unless otherwise specified.

The present invention will be described in detail with reference to the accompanying drawings and examples.

Examples 1,

In order to further obtain a process that in a deflagration experiment of gas/air premixed gas in an explosion shock tube, explosion shock waves collide a rigid fixed wall at the tail end to generate reflected waves, because the existence of the metal copper mesh porous structure device achieves wave absorption, a new thought is provided for reducing underground casualties and property loss of a mine.

As shown in fig. 1, the utility model provides a gas/air mixes device of gaseous deflagration in-process rationally placed metal copper mesh porous structure in order to reach the wave absorption energy in advance in shock tube, wherein including explosion shock tube 1, the gaseous feed system 2, pressure signal collection system 3, flame signal collection system 4, donghua data collection system 5, high pressure ignition system 6 and synchronous control system in advance outside the jar.

The explosion shock tube 1 is formed by connecting 14 sections of experimental pipelines connected end to end, 1 section of observation window experimental section and 3 sections of externally-added tubes connected end to end. Wherein, 14 sections of experimental pipelines in the explosion shock tube 1 are cold-drawn pipelines, the section shape is a square pipeline with 200mm multiplied by 200mm, the length of each section is 2500mm, two hole seats are arranged on the measuring surface and the top surface of the same position of each section of experimental pipeline, 3 groups of hole seats (6 hole seats) are reserved, and a pressure sensor or a flame sensor is arranged according to the experimental requirements; the length of the experimental section of the observation window is 1000mm, and K9 organic glass can be arranged for observing the flame change form; the diameter of the 3 sections of externally-added pipes is

The length of each section of the round steel pipe is 1200mm, and the whole explosion shock tube pipeline is connected end to endAll adopt the ring flange to connect, and the total length is 38600 mm.

The out-of-tank premixed gas supply system 2 is connected with the explosion shock tube 1, and premixed gas with required concentration in the explosion shock tube 1 is input through the gas supply pipeline controlled by the two control cabinets. The out-of-tank premixing supply system 2 comprises a premixing tank system, a vacuum pumping system and a control cabinet system. The premixing tank 211 in the premixing tank system is connected with a methane gas cylinder 212, an air compressor 213 and a vacuum pump 221 through an air supply pipeline controlled by a first control cabinet 231; the vacuum pumping system comprises two vacuum pumps 221, specifically a first-stage pump vane pump and a second-stage pump roots pump, wherein the pumping speed of the vane pump is 90m³H, the ultimate vacuum degree is 0.7Pa, and the pumping speed of the roots pump is 500m³The ultimate vacuum degree is 0.4 Pa. When the explosion shock tube 1 or the premixing tank 211 (the initial pressure is generally lower than or equal to 101.325kPa) is vacuumized, the vacuum pumping system firstly starts the first-stage pump rotary vane pump, when the pumping pressure is reduced to 100pa, the first-stage pump rotary vane pump stops, and the second-stage pump roots pump starts simultaneously to continue to vacuumize the pipeline. Meanwhile, the vacuum pump 221 is respectively connected with the explosion shock tube 1 and the premixing tank 211 through a vacuum pumping pipeline, the explosion shock tube 1 is vacuumized to convey gas/air premixed gas premixed in advance, the premixing tank 211 is vacuumized to configure the gas/air premixed gas with the concentration required by the experiment according to the Dalton partial pressure law, and the configured premixed gas needs to be kept stand for 6-8 hours to achieve full mixing; the control cabinet system comprises a first control cabinet 231 and a second control cabinet 232, wherein the input end of the first control cabinet 231 is connected with an air compressor 213 and a methane gas cylinder 212, and the output end of the first control cabinet is connected with a premixing tank 211, and the first control cabinet is used for configuring gas/air premixing gas with concentration required by an experiment according to a Dalton partial pressure law. When the gas/air premixed gas with the required concentration is prepared, the input end of the first control cabinet 231 is connected with the premixing tank 211, and the output end of the first control cabinet is connected with the second control cabinet 232; the input end of the second control cabinet 232 is connected with the first control cabinet 231, the output end is connected with 3 gas inlet ports on the explosion shock tube 1, and gas/air premixed gas with the initial pressure of 101.325kpa is input.

The pressure signal acquisition system 3 specifically comprises 8 piezoelectric pressure sensors, the piezoelectric pressure sensors are equidistantly arranged on an experimental pipeline of the explosion shock tube 1, and acquired pressure signals are transmitted to the Donghua data acquisition system 5 through data lines. Wherein pressure sensor selects the pressure sensor of U.S. PCB company, and this sensor model is M111A22, and the main parameter is: the sensitivity is 0.145mv/kpa, the maximum range is 6.9MPa, the linearity meets less than or equal to 1% FS, the resonance frequency is more than or equal to 500KHz, the rise time is less than or equal to 1 mu s, and the working temperature is 73-135 ℃.

As shown in fig. 2, for the utility model discloses in the gas/air mixes flame signal collection system 4's in the gas deflagration experiment test system in advance structural schematic diagram, each sensor seat 41 all connects a photodiode 43's input through an optic fibre 42, photodiode 43 is used for converting light signal into the signal of telecommunication, a power 44 and a resistance 45's one end of parallel connection respectively is connected to each photodiode 43's output, oscilloscope 46 and donghua data collection system 5 are connected respectively to each power 44 and resistance 45's the other end, synchronous control system is still connected to donghua data collection system 5. The acquisition system is an autonomously designed acquisition system and is arranged on a plurality of sections of experimental pipelines which are connected end to end. The basic idea of flame signal acquisition is: converting the optical signal into an electric signal and transmitting the electric signal to the Donghua data acquisition system 5; the specific process is as follows: when flame light passing through the gas/air premixed gas deflagration parameters reaches the position of the optical fiber sensor seat 41, an optical signal is transmitted into the optical fiber 42 from a gap of the optical fiber sensor seat 41 and then is guided into the photodiode 43(GT101) in the optical fiber sensor through the optical fiber 42, the current of the photodiode 43(GT101) is changed due to the change of the light, and the optical signal can be converted into an electric signal through the photodiode 43; the electric signals are input into a data acquisition system, the generated time difference is calculated according to the occurrence time of the flame voltage signals of the optical fiber sensors at different positions, and the distance between the corresponding optical fiber sensors recorded when the optical fiber sensors are arranged is divided by the time difference to obtain the corresponding flame propagation speed.

The donghua data acquisition system 5 is configured with a 16-channel data acquisition card (sampling frequency is 1MHz) and a DHDAS dynamic signal acquisition and analysis system, software adopted by the DHDAS dynamic signal acquisition and analysis system provides a Chinese interface convenient for operation, and different parameters can be set independently, for example: triggering level, data acquisition and input modes and the like, and simultaneously completing direct reading of data curves and the like on an operation interface.

The high-voltage ignition system 6 adopts the principle that 220V voltage breaks down partial air to form arc to induce 5000V high-voltage discharge, and comprises a capacitor and a diode, wherein the anode of the capacitor and the cathode of the diode are connected with a 220V power supply, the cathode of the capacitor and the anode of the diode are connected with a ground wire, the anode of the capacitor is used as the high-voltage anode of the high-voltage ignition system, a discharge switch is triggered to switch on a circuit after the required voltage is reached, the ground wire and the low-voltage anode output by a synchronous control system generate discharge, the low-voltage anode and the ground wire generate discharge to break down an air medium between the high-voltage anode and the ground wire, and the ignition of gas/air premixed gas is completed.

The synchronous control system relates to a high-pressure ignition system 6, a pressure data acquisition system 3, a flame data acquisition system 4 and a Donghua data acquisition system 5. Because the time scale of data measurement is very small and can reach a delicate magnitude, the reflection time of a human body is far short, and therefore the transient synchronous time control is required to be achieved. The synchronous control system is composed of a function signal generator 71, a time delayer 72 and a solid-state relay 73. The basic principle is as follows: an output port of the function signal generator 71 provides a standard TTL signal to enter an input port of the time delay unit 72, one path of a signal output by the time delay unit 72 is connected with the pressure signal acquisition system 3, the flame signal acquisition system 4 and the Donghua data acquisition system 5 and starts to acquire data, the other path of the signal is connected with the solid-state relay 73, and an outlet end of the solid-state relay 73 is connected with the high-pressure ignition system 6 and is used for finishing ignition of gas/air premixed gas.

Based on above-mentioned gas/air mixes introduction to each component in the gaseous deflagration experimental system in advance, the utility model designs a paste metal copper mesh porous structure in order to reach the device of wave absorption energy absorption at the terminal rational design of explosion shock tube, for in the actual coal mine production, takes place gas explosion accident and reduces mine underground casualties and loss of property and provide new method, and it includes following step:

1) placing a metal copper net at the tail end of the shock tube;

according to the literature, the metal copper mesh belongs to a porous material, and when the metal copper mesh is pasted at the tail end of an explosive shock tube, the metal copper mesh divides a tail end closed cavity into a plurality of fine unit grids. The current research theory considers that the porous material achieves wave absorption and energy absorption theories in the explosion process, one theory is a thermal theory, namely a cold wall effect, when flame passes through the porous material, because a closed cavity is divided into a plurality of fine units by the porous material, the porous structure has a high specific surface, the heat absorption performance is improved, a large amount of heat is absorbed, the temperature of the flame is reduced to a certain degree, and finally the flame is extinguished, so that the wave absorption and energy absorption are achieved. Another theory is the chain reaction theory, i.e. the wall effect, which suggests that the deflagration process of a gas is not the result of a direct interaction between gas molecules, but is subject to external energy, such as: when flame passes through the porous material, because the porous materials have high specific surface areas and are mutually overlapped and same layer by layer, a large amount of active free radicals generated in the reaction process collide with the wall surface of the porous material to be destroyed, so that the active free radicals really participating in the reaction are reduced, the flame is extinguished, and the purposes of wave absorption and energy absorption are achieved. More researchers think that the two theories of the porous material in the process of inhibiting the propagation of flame and reducing the overpressure of the shock wave are simultaneously carried out, so that the effects of wave absorption and energy absorption are achieved.

The utility model discloses in order to make the effect that reaches the wave absorption energy-absorbing that metal copper mesh porous material can be better, avoid metal copper mesh too little because of the hole simultaneously, metal copper mesh's intensity is low excessively, causes tearing and destroying of shock wave to metal copper mesh. Therefore, the utility model selects the 80-mesh copper mesh, which not only ensures a certain specific surface area, but also ensures a certain strength. Meanwhile, research shows that the filling density and the void ratio of the porous material have important influence on the flame propagation and the pressure restraining magnitude. Therefore, when the metal copper mesh is adhered to the tail end of the explosive shock tube, the filling density of the metal copper mesh is ensured and the reason for adhering the metal copper mesh to the tail end of the explosive shock tube is avoidedThe filling is too big to cause the empty rate to be too small, so the utility model divides the metal copper mesh into 100mm multiplied by 100mm square, and folds the metal copper mesh into 10mm multiplied by 10mm square small blocks, the middle part adopts the bolt fixation, the folded metal copper mesh small blocks are packed into the metal copper mesh with the diameter of the metal copper mesh

The cylinder is adhered to the external tube connected with the tail end of the explosion shock tube, so that the filling density and the void ratio of the metal copper mesh are ensured, and the most efficient wave absorption and energy absorption effects of the metal copper mesh are exerted.

2) Gas/air premixed gas is configured outside the tank, and standing is carried out for 6-8 hours for later use;

3) checking the air tightness of the explosion shock tube by adopting a positive pressure leak detection mode, and vacuumizing the explosion shock tube;

4) controlling 9.5 percent of gas/air premixed gas entering an explosion shock tube by using a control cabinet, wherein the initial pressure is 101.325 kpa;

5) measuring the whole-course pressure and flame propagation speed in the shock tube 1 by adopting a flame signal acquisition system and a pressure signal acquisition system, and transmitting the measured whole-course pressure and flame propagation speed to a Donghua data acquisition system;

6) and (5) analyzing experimental data.

Examples 2,

The utility model discloses well main research is placed the wave absorption energy absorption effect that disappears of metal copper mesh porous material to gas/air premixed gas deflagration experiment at explosion shock tube end, consequently, according to the utility model discloses the setting of device in the embodiment 1, this experiment has set up 3 groups: firstly, gas/air premixed gas with the concentration of 9.5 percent, and the tail end of an explosion shock tube is not provided with a metal copper mesh porous material, as shown in figure 3; secondly, gas/air premixed gas with the concentration of 9.5 percent, and a metal copper mesh cylinder with the length of 100mm is stuck at the tail end of the explosion shock tube, as shown in figure 4; thirdly, gas/air premixed gas with the concentration of 9.5 percent, and a metal copper mesh cylinder with the length of 350mm is stuck at the tail end of the explosion shock tube, as shown in figure 5, 3 groups of the above 3 working conditions are repeatedly made, so as to ensure the accuracy of experimental data.

In order to research the wave-absorbing and energy-absorbing effects of placing a metal copper mesh porous material at the tail end of an explosion shock tube on the deflagration experiment of gas/air premixed gas, 8 groups of pressure sensors and flame sensors are respectively arranged on the top surface and the measurement at the same position according to a graph 6, and the distances between the sensors and an ignition end are shown in a table 1.

Table 1 sensor arrangement on detonation shock tube

In the example, 3 working conditions of the wave-absorbing and energy-absorbing effect experiment of the metal copper mesh porous material in the gas/air premixed gas deflagration experiment are repeatedly made into 3 groups, and the average test experiment data of the 3 groups are as follows:

TABLE 2 pressure sensor data without metallic copper mesh porous material

TABLE 3 flame sensor data without metallic copper mesh porous material

Table 4100 mm pressure sensor data for metallic copper mesh cylinder

Flame sensor data in the form of a copper mesh cylinder of 5100 mm in table

Table 6350 mm pressure sensor data for a copper mesh cylinder

TABLE 7350 mm flame sensor data for a copper mesh cylinder

Comparing and analyzing the data of the porous structure of the metal copper mesh which is not arranged at the tail end of the explosion shock tube, the data of the porous structure of the metal copper mesh which is 100mm long and is arranged at the tail end of the explosion shock tube and the data (tables 2-7) of the porous structure of the metal copper mesh which is 350mm long and is arranged at the tail end of the explosion shock tube respectively, wherein the results are as follows:

TABLE 8 pressure sensor data averages

TABLE 9 attenuation Rate

As shown in fig. 7, from the results of the overpressure decay rate trend experiments, it is clear from tables 8 to 9 and fig. 7 that the apparatus having the porous metal copper mesh structure can play a role of wave-absorbing and energy-absorbing in the gas/air premixed gas deflagration experiment.

Claims (6)

1. The utility model provides a device of metal copper mesh porous structure wave absorption energy absorption in realizing gas/air mixes gaseous deflagration experiment in advance which characterized in that: the device comprises an explosion shock tube, an out-of-tank premixed gas supply system, a pressure signal acquisition system, a flame signal acquisition system, a Donghua data acquisition system, a high-pressure ignition system and a synchronous control system;

the explosion shock tube comprises a plurality of experimental pipelines and 1 visual observation window experimental section pipeline which are connected end to end; the tail end of the explosion shock tube is provided with a metal copper mesh porous structure;

the tank outside premixed gas supply system is communicated with the inside of the explosion shock tube and is used for generating premixed gas with a preset equivalence ratio according to experimental requirements and inputting the premixed gas into the explosion shock tube;

the pressure signal acquisition system and the flame signal acquisition system are arranged on the side wall of each section of the experimental pipeline and are used for measuring the rule of the whole-course pressure and the flame propagation speed in the explosion shock wave pipe, and the measurement result is sent to the synchronous control system through the data acquisition system;

the Donghua data acquisition system is connected with the pressure signal acquisition system and the flame signal acquisition system and is used for acquiring and analyzing whole-course data in the explosion shock tube and acquiring and analyzing DHDAS dynamic signals;

the high-voltage ignition system is connected with the end part of the shock tube and is used for igniting the premixed gas in the shock tube;

the synchronous control system is used for synchronously controlling the flame signal acquisition system, the pressure signal acquisition system, the Donghua data acquisition system and the high-pressure ignition system;

the Donghua data acquisition system comprises a 16-channel data acquisition card and a DHDAS dynamic signal acquisition and analysis system.

2. The apparatus of claim 1, wherein: in the device, the explosion shock tube is formed by connecting a plurality of sections of experimental pipelines connected end to end, 1 section of experimental section pipeline of a visual observation window and 3 sections of externally-added tubes connected end to end in sequence; the wall surface of an outer increase pipe at the tail end of the explosion shock tube is provided with a metal copper mesh porous structure;

the out-of-tank premixed gas supply system comprises a premixed tank system, a vacuum pumping system and a control cabinet system; the system comprises a premixing tank system, a methane gas cylinder and an air compressor, wherein the vacuumizing system comprises two connected vacuum pumps, and the control cabinet system comprises a first control cabinet and a second control cabinet which are connected; the premixing tank is connected with the methane gas cylinder, the air compressor and the vacuum pump through an air supply pipeline controlled by the first control cabinet, so that premixed gas in the premixing tank is input into the explosion shock tube connected with the premixing tank through the air supply pipeline; the vacuum pump is also connected with the explosion shock tube; the second control cabinet is connected with 3 air inlet ports on the explosion shock tube;

the pressure signal acquisition system comprises a plurality of piezoelectric pressure sensors; each piezoelectric pressure sensor is arranged on a plurality of experimental pipelines connected end to end, and transmits the acquired pressure signals to the Donghua data acquisition system through data lines;

the flame signal acquisition system comprises an optical fiber, an optical fiber sensor, a photoelectric integrator and a data acquisition system which are sequentially connected, is arranged on the end-to-end multi-section experimental pipelines, converts optical signals into electric signals and transmits the electric signals to the Donghua data acquisition system;

the high-voltage ignition system comprises capacitors and diodes and is arranged at the foremost ends of the experiment pipelines which are connected end to end, the anodes of the capacitors and the cathodes of the diodes are connected with a 220V power supply, and the cathodes of the capacitors and the anodes of the diodes are connected with a ground wire to finish ignition of the gas/air premixed gas;

the synchronous control system is composed of a function signal generator, a time delayer and a solid-state relay, wherein an output port of the function signal generator is connected with an input port of the time delayer, output ports of the time delayer are respectively connected with the flame signal acquisition system, the pressure signal acquisition system, the Donghua data acquisition system and the solid-state relay, and an output port of the solid-state relay is connected with the high-pressure ignition system.

3. The apparatus of claim 2, wherein: the experimental pipelines are cold-drawn pipelines, and the cross sections of the experimental pipelines are square;

the number of the experimental pipelines is 14 sections;

2 side surfaces and top surfaces of the same position on each section of the experimental pipeline are respectively provided with two hole seats for arranging a pressure sensor or a flame sensor;

k9 organic glass is arranged in the experimental section of the observation window;

the external pipe is a round steel pipe;

all pipelines in the explosion shock tube are connected end to end by flanges.

4. The apparatus of claim 2, wherein: the premixing tank is connected with the first control cabinet through a ball valve and a high-pressure air pump line;

the 2 vacuum pumps are a first-stage pump rotary vane pump and a second-stage pump roots pump; the primary pump rotary vane pump and the secondary pump roots pump are communicated with the interior of the shock tube through high-pressure gas pump lines, and control ends of the primary pump rotary vane pump and the secondary pump roots pump are connected with the first control cabinet and the second control cabinet and are used for vacuumizing, charging and distributing the shock tube according to control signals of the first control cabinet and the second control cabinet;

and the output port of the first control cabinet is respectively connected with the air compressor, the methane gas cylinder and the second control cabinet and is used for respectively filling methane and air into the premixing tank according to a predetermined volume percentage according to a partial pressure law.

5. The apparatus of claim 2, wherein: the number of the piezoelectric pressure sensors is 8-16;

and the piezoelectric pressure sensors are arranged on the plurality of experimental pipelines connected end to end at equal intervals.

6. The apparatus of claim 1, wherein: software adopted by the DHDAS dynamic signal acquisition and analysis system can independently set different parameters and is connected with the pressure signal acquisition system and the flame signal acquisition system.

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