CN110672944A - Simulation test method, system, medium and equipment suitable for fire extinguishing device detection - Google Patents
Simulation test method, system, medium and equipment suitable for fire extinguishing device detection Download PDFInfo
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Abstract
The invention provides a simulation test method, a system, a medium and equipment suitable for fire extinguishing device detection, which comprise the following steps: setting a timed interrupt time; acquiring a voltage value of the electric detonator: acquiring information according to the AD value to acquire voltage value information of the electric detonator; the method comprises the following steps of (1) acquiring an energy value of the electric detonator: acquiring the energy value of the electric detonator passing through the electric detonator in unit time according to the voltage value information of the electric detonator and the resistance value parameter of the electric detonator, and acquiring the energy value information of the electric detonator in unit time; setting an accumulated time; judging accumulated energy values: acquiring accumulated energy value information of the simulated electric detonator according to the accumulated time setting information, the electric detonator energy value information in unit time and the electric detonator disconnection energy threshold parameter; comparing the accumulated energy value in the set accumulation time with the electric detonator disconnection energy threshold value to obtain the direct electric detonator disconnection control information or zero clearing control information; the invention can reduce the test cost of the automatic fire extinguishing device.
Description
Technical Field
The invention relates to the technical field of fire fighting, in particular to a simulation test method, a simulation test system, a simulation test medium and simulation test equipment suitable for fire extinguishing device detection, and particularly relates to a method for simulating the relation between the disconnection time of a fire extinguishing electric detonator and driving voltage.
Background
1211/1301 fire extinguishing bottles equipped in the automatic fire extinguishing device are mostly provided with electric explosion tubes, and after receiving a driving signal, the valve of the fire extinguishing bottle is opened to release the fire extinguishing agent to achieve the purpose of fire extinguishing. When detecting the bottle spraying function of the automatic fire extinguishing device, a real fire extinguishing bottle is often used, so that the test cost is increased, and the environment-friendly and energy-saving concept is not met.
Therefore, it is particularly important to develop a simulated fire-extinguishing bottle to replace a real fire-extinguishing bottle to complete the function test of the automatic fire-extinguishing device in the ordinary test. The existing simulated fire extinguishing bottle can only cut off the electric detonator within a specified time when receiving a fixed voltage driving signal, and does not achieve the function of simulating real electric detonator cutting off.
Patent document CN207545683U discloses a fire control electricity explodes valve, which comprises a supporting plate, the top of backup pad is equipped with the supporting seat, the bilateral symmetry of backup pad is provided with bolt one, the top of supporting seat is equipped with the urceolus, the one end of urceolus is equipped with sealed lid one, sealed lid one is kept away from one side of urceolus and is equipped with the fixed plate, the bilateral symmetry of fixed plate is provided with bolt two, the one end of bolt two runs through in fixed plate and sealed lid one and extend to the tip of urceolus, one side middle part of fixed plate is equipped with the inlet tube, the inside of urceolus is equipped with the inner tube, the inside of inner tube is equipped with the gas pipeline one that is close to the inlet tube, the one end of inlet tube runs through in. The pressure diaphragm is disconnected from the original balance state, so that the fire extinguishing agent is sprayed out from the spray head to extinguish fire. However, when the bottle spraying function of the automatic fire extinguishing device is detected, a real fire extinguishing bottle still needs to be used, so that the test cost is increased, and the environment-friendly and energy-saving concept is not met.
Disclosure of Invention
In view of the shortcomings in the prior art, it is an object of the present invention to provide a simulation test method, system, medium and apparatus suitable for fire extinguishing apparatus detection.
The invention provides a simulation test method suitable for detecting a fire extinguishing device, which comprises the following steps: setting timed interruption time: setting the timed interruption time within a preset range, and acquiring the set result information of the timed interruption time; acquiring a voltage value of the electric detonator: setting result information according to the timing interruption time, and acquiring an AD value of the driving voltage of the electric detonator in each interruption time to acquire AD value acquisition information; acquiring information according to the AD value to acquire voltage value information of the electric detonator; the method comprises the following steps of (1) acquiring an energy value of the electric detonator: acquiring the energy value of the electric detonator passing through the electric detonator in unit time according to the voltage value information of the electric detonator and the resistance value parameter of the electric detonator, and acquiring the energy value information of the electric detonator in unit time; setting an accumulated time: setting accumulation time, and acquiring accumulation time setting information; judging accumulated energy values: acquiring accumulated energy value information of the simulated electric detonator according to the accumulated time setting information, the electric detonator energy value information in unit time and the electric detonator disconnection energy threshold parameter; selecting and controlling: comparing the accumulated energy value in the set accumulation time with the electric detonator disconnection energy threshold value to obtain the direct electric detonator disconnection control information or zero clearing control information; and a cumulative energy value recalculation step: repeatedly executing the accumulated energy value judgment step according to the zero clearing control information; a simulation test result obtaining step: directly disconnecting control information according to the simulated electric detonator to obtain simulated test result information of the fire extinguishing device; the direct disconnection control information of the electric detonator is used for guiding the direct disconnection behavior of the electric detonator; and the zero clearing control information guides zero clearing action of the accumulated energy value calculation.
Preferably, the timer interrupt time setting step includes: an interruption time limiting step: setting the timed interruption time to a time value less than 1ms, and acquiring the set result information of the timed interruption time; the electric detonator voltage value obtaining step comprises the following steps: the singlechip selection step: and selecting a singlechip with the AD resolution of 12 bits, acquiring the AD value of the driving voltage of the electric detonator within each interrupt time, wherein the AD value is less than or equal to 4096, and acquiring AD value acquisition information and AD value maximum threshold information.
Preferably, the step of obtaining the voltage value of the electric detonator further comprises: the method comprises the following steps of (1) constructing an electric detonator voltage value calculation formula: constructing a voltage division circuit formula according to the maximum threshold value information of the AD value, and acquiring the voltage value calculation model information of the electric detonator; the voltage division circuit is constructed according to the following formula:
wherein U is a driving voltage value, U1The voltage value is the voltage value of the electric detonator; and calculating model information according to the AD value acquisition information and the voltage value of the electric detonator, and acquiring the voltage value information of the electric detonator.
Preferably, the accumulated energy value determining step includes: setting an accumulated time: setting the accumulation time to be 100ms, and acquiring accumulation time setting information; setting the disconnection energy threshold of the electric detonator: and setting the disconnection energy threshold of the electric detonator to be 108 mJ, and obtaining the disconnection energy threshold parameter of the electric detonator.
According to the invention, the simulation test system suitable for the detection of the fire extinguishing device comprises: the timed interruption time setting module: setting the timed interruption time to a time value less than 1ms, and acquiring the set result information of the timed interruption time; the electric detonator voltage value acquisition module: setting result information according to the timing interruption time, and acquiring an AD value of the driving voltage of the electric detonator in each interruption time to acquire AD value acquisition information; acquiring information according to the AD value to acquire voltage value information of the electric detonator; the energy value of the electric detonator obtains the module: acquiring the energy value of the electric detonator passing through the electric detonator in unit time according to the voltage value information of the electric detonator and the resistance value parameter of the electric detonator, and acquiring the energy value information of the electric detonator in unit time; an accumulated time setting module: setting accumulation time, and acquiring accumulation time setting information; an accumulated energy value judgment module: acquiring accumulated energy value information of the simulated electric detonator according to the accumulated time setting information, the electric detonator energy value information in unit time and the electric detonator disconnection energy threshold parameter; selecting a control module: comparing the accumulated energy value in the set accumulation time with the electric detonator disconnection energy threshold value to obtain the direct electric detonator disconnection control information or zero clearing control information; an accumulated energy value recalculation module: according to the zero clearing control information, repeatedly executing the accumulated energy value judgment module; the simulation test result acquisition module: directly disconnecting control information according to the simulated electric detonator to obtain simulated test result information of the fire extinguishing device; the direct disconnection control information of the electric detonator is used for guiding the direct disconnection behavior of the electric detonator; and the zero clearing control information guides zero clearing action of the accumulated energy value calculation.
Preferably, the electric detonator voltage value obtaining module includes: the single chip microcomputer selection module: and selecting a singlechip with the AD resolution of 12 bits, acquiring the AD value of the driving voltage of the electric detonator within each interrupt time, wherein the AD value is less than or equal to 4096, and acquiring AD value acquisition information and AD value maximum threshold information.
Preferably, the electrical detonator voltage value obtaining module further comprises: the electric detonator voltage value calculation formula construction module comprises: constructing a voltage division circuit formula according to the maximum threshold value information of the AD value, and acquiring the voltage value calculation model information of the electric detonator; the voltage division circuit is constructed according to the following formula:
wherein U is a driving voltage value, U1The voltage value is the voltage value of the electric detonator; and calculating model information according to the AD value acquisition information and the voltage value of the electric detonator, and acquiring the voltage value information of the electric detonator.
Preferably, the accumulated energy value determination module includes: an accumulated time setting module: setting the accumulation time to be 100ms, and acquiring accumulation time setting information; the electric detonator disconnection energy threshold setting module: and setting the disconnection energy threshold of the electric detonator to be 108 mJ, and obtaining the disconnection energy threshold parameter of the electric detonator.
According to the present invention, a computer-readable storage medium is provided, in which a computer program is stored, which computer program, when being executed by a processor, carries out the steps of a simulation test method suitable for fire-extinguishing device detection.
According to the invention, the simulation test equipment suitable for the detection of the fire extinguishing device comprises: a controller; the controller comprises a computer readable storage medium storing a computer program which, when executed by a processor, performs the steps of a simulation test method suitable for fire suppression apparatus detection; alternatively, the controller includes an analog test system adapted for fire suppression device detection.
Compared with the prior art, the invention has the following beneficial effects:
1. the method is embedded into the simulated fire extinguishing bottle, and the disconnection time of the electric detonator can be determined according to the received different fire extinguishing bottle driving voltage values, so that the self-adaptability of the simulated fire extinguishing bottle is enhanced;
2. the invention can improve the practicability of the simulated fire-extinguishing bottle and achieve the aim of simulating a real 1211/1301 fire-extinguishing bottle;
3. the invention can reduce the test cost of the automatic fire extinguishing device.
Drawings
Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:
FIG. 1 is a schematic flow chart of the method of the present invention.
FIG. 2 is a system framework diagram of the present invention.
Fig. 3 is a schematic flow chart in the embodiment of the invention.
Detailed Description
The present invention will be described in detail with reference to specific examples. The following examples will assist those skilled in the art in further understanding the invention, but are not intended to limit the invention in any way. It should be noted that it would be obvious to those skilled in the art that various changes and modifications can be made without departing from the spirit of the invention. All falling within the scope of the present invention.
The invention provides a simulation test method suitable for detecting a fire extinguishing device, which comprises the following steps: setting timed interruption time: setting the timed interruption time within a preset range, and acquiring the set result information of the timed interruption time; acquiring a voltage value of the electric detonator: setting result information according to the timing interruption time, and acquiring an AD value of the driving voltage of the electric detonator in each interruption time to acquire AD value acquisition information; acquiring information according to the AD value to acquire voltage value information of the electric detonator; the method comprises the following steps of (1) acquiring an energy value of the electric detonator: acquiring the energy value of the electric detonator passing through the electric detonator in unit time according to the voltage value information of the electric detonator and the resistance value parameter of the electric detonator, and acquiring the energy value information of the electric detonator in unit time; setting an accumulated time: setting accumulation time, and acquiring accumulation time setting information; judging accumulated energy values: acquiring accumulated energy value information of the simulated electric detonator according to the accumulated time setting information, the electric detonator energy value information in unit time and the electric detonator disconnection energy threshold parameter; selecting and controlling: comparing the accumulated energy value in the set accumulation time with the electric detonator disconnection energy threshold value to obtain the direct electric detonator disconnection control information or zero clearing control information; and a cumulative energy value recalculation step: repeatedly executing the accumulated energy value judgment step according to the zero clearing control information; a simulation test result obtaining step: directly disconnecting control information according to the simulated electric detonator to obtain simulated test result information of the fire extinguishing device; the direct disconnection control information of the electric detonator is used for guiding the direct disconnection behavior of the electric detonator; and the zero clearing control information guides zero clearing action of the accumulated energy value calculation.
Preferably, the timer interrupt time setting step includes: an interruption time limiting step: setting the timed interruption time to a time value less than 1ms, and acquiring the set result information of the timed interruption time; the electric detonator voltage value obtaining step comprises the following steps: the singlechip selection step: and selecting a singlechip with the AD resolution of 12 bits, acquiring the AD value of the driving voltage of the electric detonator within each interrupt time, wherein the AD value is less than or equal to 4096, and acquiring AD value acquisition information and AD value maximum threshold information.
Preferably, the step of obtaining the voltage value of the electric detonator further comprises: the method comprises the following steps of (1) constructing an electric detonator voltage value calculation formula: constructing a voltage division circuit formula according to the maximum threshold value information of the AD value, and acquiring the voltage value calculation model information of the electric detonator; the voltage division circuit is constructed according to the following formula:
wherein U is a driving voltage value, U1The voltage value is the voltage value of the electric detonator; and calculating model information according to the AD value acquisition information and the voltage value of the electric detonator, and acquiring the voltage value information of the electric detonator.
Preferably, the accumulated energy value determining step includes: setting an accumulated time: setting the accumulation time to be 100ms, and acquiring accumulation time setting information; setting the disconnection energy threshold of the electric detonator: and setting the disconnection energy threshold of the electric detonator to be 108 mJ, and obtaining the disconnection energy threshold parameter of the electric detonator.
Specifically, in one embodiment, the energy required for disconnecting the electric detonator is known to be a fixed value, and under the condition that the resistance value of the electric detonator is not changed, the energy, namely voltage, applied to the electric detonator is inversely proportional to the disconnection time of the electric detonator.
After a plurality of tests, when the voltage of 5-40V is applied to the electric detonator of the real fire-extinguishing bottle, the disconnection time of the electric detonator is acquired and is T, the range is 100-1 ms, the resistance value of the electric detonator is known to be R, and the formula is shown according to the formulaThe electric detonator needs a certain energy value when being disconnected, the delta Q is the energy needed by the disconnection of the electric detonator, the U is a driving voltage value, the R is the resistance value of the electric detonator, the T is the disconnection time of the electric detonator, the known driving voltage U and the resistance value R of the electric detonator can be calculated, and the energy delta Q for driving the electric detonator to be driven in unit time T can be calculated, so that the energy needed by the disconnection of the electric detonator is 108 millijoules. And judging that the accumulated energy passing through the electric explosion tube exceeds 108 mJ within the longest time of 100ms when the electric explosion tube receives the spray bottle driving signal.
Specifically, in one embodiment, a simulation test method for fire suppression equipment detection comprises the following steps:
1. the design timing interruption time is 500us (can set up to be less than 1ms can, earlier stage experiment verifies, the electric blasting tube disconnection time scope is 1ms ~ 100ms under the different voltage, therefore software interruption time need be less than 1ms and just can accurately calculate disconnection time), gather electric blasting tube driving voltage's AD value in the time T of interrupting at every turn, the singlechip AD resolution ratio that known simulation fire-extinguishing bottle chose to use is 12 bits, so the AD value is 4096 at most, according to following bleeder circuit formula:
thereby calculating the voltage value formula of the electric detonator and calculating the voltage U1;
2. According to the energy formula, the energy value passing through the electric detonator in unit time delta t can be calculated by the following formula:
wherein, the resistance value R of the electric detonator
3. Calculating the accumulated energy value passing through the simulation electric shock tube, and if the accumulated energy value in 100ms reaches 108 mJ, directly disconnecting the simulation electric shock tube; otherwise, zero clearing is carried out, the accumulated energy value is recalculated, and the simulated electric detonator is considered to not receive the spray bottle driving signal.
The person skilled in the art can understand that the simulation test method for fire extinguishing apparatus detection provided by the present invention is an embodiment of the simulation test system for fire extinguishing apparatus detection provided by the present invention. That is, the simulation test system for fire extinguishing apparatus detection may be implemented by executing the flow of steps of the simulation test method for fire extinguishing apparatus detection.
According to the invention, the simulation test system suitable for the detection of the fire extinguishing device comprises: the timed interruption time setting module: setting the timed interruption time to a time value less than 1ms, and acquiring the set result information of the timed interruption time; the electric detonator voltage value acquisition module: setting result information according to the timing interruption time, and acquiring an AD value of the driving voltage of the electric detonator in each interruption time to acquire AD value acquisition information; acquiring information according to the AD value to acquire voltage value information of the electric detonator; the energy value of the electric detonator obtains the module: acquiring the energy value of the electric detonator passing through the electric detonator in unit time according to the voltage value information of the electric detonator and the resistance value parameter of the electric detonator, and acquiring the energy value information of the electric detonator in unit time; an accumulated time setting module: setting accumulation time, and acquiring accumulation time setting information; an accumulated energy value judgment module: acquiring accumulated energy value information of the simulated electric detonator according to the accumulated time setting information, the electric detonator energy value information in unit time and the electric detonator disconnection energy threshold parameter; selecting a control module: comparing the accumulated energy value in the set accumulation time with the electric detonator disconnection energy threshold value to obtain the direct electric detonator disconnection control information or zero clearing control information; an accumulated energy value recalculation module: according to the zero clearing control information, repeatedly executing the accumulated energy value judgment module; the simulation test result acquisition module: directly disconnecting control information according to the simulated electric detonator to obtain simulated test result information of the fire extinguishing device; the direct disconnection control information of the electric detonator is used for guiding the direct disconnection behavior of the electric detonator; and the zero clearing control information guides zero clearing action of the accumulated energy value calculation.
Preferably, the electric detonator voltage value obtaining module includes: the single chip microcomputer selection module: and selecting a singlechip with the AD resolution of 12 bits, acquiring the AD value of the driving voltage of the electric detonator within each interrupt time, wherein the AD value is less than or equal to 4096, and acquiring AD value acquisition information and AD value maximum threshold information.
Preferably, the electrical detonator voltage value obtaining module further comprises: the electric detonator voltage value calculation formula construction module comprises: constructing a voltage division circuit formula according to the maximum threshold value information of the AD value, and acquiring the voltage value calculation model information of the electric detonator; the voltage division circuit is constructed according to the following formula:
wherein U is a driving voltage value, U1The voltage value is the voltage value of the electric detonator; and calculating model information according to the AD value acquisition information and the voltage value of the electric detonator, and acquiring the voltage value information of the electric detonator.
Preferably, the accumulated energy value determination module includes: an accumulated time setting module: setting the accumulation time to be 100ms, and acquiring accumulation time setting information; the electric detonator disconnection energy threshold setting module: and setting the disconnection energy threshold of the electric detonator to be 108 mJ, and obtaining the disconnection energy threshold parameter of the electric detonator.
According to the present invention, a computer-readable storage medium is provided, in which a computer program is stored, which computer program, when being executed by a processor, carries out the steps of a simulation test method suitable for fire-extinguishing device detection.
According to the invention, the simulation test equipment suitable for the detection of the fire extinguishing device comprises: a controller; the controller comprises a computer readable storage medium storing a computer program which, when executed by a processor, performs the steps of a simulation test method suitable for fire suppression apparatus detection; alternatively, the controller includes an analog test system adapted for fire suppression device detection.
The method is embedded into the simulated fire extinguishing bottle, and the disconnection time of the electric detonator can be determined according to the received different fire extinguishing bottle driving voltage values, so that the self-adaptability of the simulated fire extinguishing bottle is enhanced; the invention can improve the practicability of the simulated fire-extinguishing bottle and achieve the aim of simulating a real 1211/1301 fire-extinguishing bottle; the invention can reduce the test cost of the automatic fire extinguishing device.
Those skilled in the art will appreciate that, in addition to implementing the systems, apparatus, and various modules thereof provided by the present invention in purely computer readable program code, the same procedures can be implemented entirely by logically programming method steps such that the systems, apparatus, and various modules thereof are provided in the form of logic gates, switches, application specific integrated circuits, programmable logic controllers, embedded microcontrollers and the like. Therefore, the system, the device and the modules thereof provided by the present invention can be considered as a hardware component, and the modules included in the system, the device and the modules thereof for implementing various programs can also be considered as structures in the hardware component; modules for performing various functions may also be considered to be both software programs for performing the methods and structures within hardware components.
The foregoing description of specific embodiments of the present invention has been presented. It is to be understood that the present invention is not limited to the specific embodiments described above, and that various changes or modifications may be made by one skilled in the art within the scope of the appended claims without departing from the spirit of the invention. The embodiments and features of the embodiments of the present application may be combined with each other arbitrarily without conflict.
Claims (10)
1. A simulation test method suitable for fire suppression device detection, comprising:
setting timed interruption time: setting the timed interruption time within a preset range, and acquiring the set result information of the timed interruption time;
acquiring a voltage value of the electric detonator: setting result information according to the timing interruption time, and acquiring an AD value of the driving voltage of the electric detonator in each interruption time to acquire AD value acquisition information;
acquiring information according to the AD value to acquire voltage value information of the electric detonator;
the method comprises the following steps of (1) acquiring an energy value of the electric detonator: acquiring the energy value of the electric detonator passing through the electric detonator in unit time according to the voltage value information of the electric detonator and the resistance value parameter of the electric detonator, and acquiring the energy value information of the electric detonator in unit time;
setting an accumulated time: setting accumulation time, and acquiring accumulation time setting information;
judging accumulated energy values: acquiring accumulated energy value information of the simulated electric detonator according to the accumulated time setting information, the electric detonator energy value information in unit time and the electric detonator disconnection energy threshold parameter;
selecting and controlling: comparing the accumulated energy value in the set accumulation time with the electric detonator disconnection energy threshold value to obtain the direct electric detonator disconnection control information or zero clearing control information;
and a cumulative energy value recalculation step: repeatedly executing the accumulated energy value judgment step according to the zero clearing control information;
a simulation test result obtaining step: directly disconnecting control information according to the simulated electric detonator to obtain simulated test result information of the fire extinguishing device;
the direct disconnection control information of the electric detonator is used for guiding the direct disconnection behavior of the electric detonator;
and the zero clearing control information guides zero clearing action of the accumulated energy value calculation.
2. The simulated test method for fire suppression apparatus detection as recited in claim 1, wherein said timed interrupt time setting step comprises:
an interruption time limiting step: setting the timed interruption time to a time value less than 1ms, and acquiring the set result information of the timed interruption time;
the electric detonator voltage value obtaining step comprises the following steps:
the singlechip selection step: and selecting a singlechip with the AD resolution of 12 bits, acquiring the AD value of the driving voltage of the electric detonator within each interrupt time, wherein the AD value is less than or equal to 4096, and acquiring AD value acquisition information and AD value maximum threshold information.
3. The simulation test method suitable for fire extinguishing apparatus detection according to claim 2, wherein the electrical squib voltage value obtaining step further comprises:
the method comprises the following steps of (1) constructing an electric detonator voltage value calculation formula: constructing a voltage division circuit formula according to the maximum threshold value information of the AD value, and acquiring the voltage value calculation model information of the electric detonator; the voltage division circuit is constructed according to the following formula:
wherein U is a driving voltage value, U1The voltage value is the voltage value of the electric detonator;
and calculating model information according to the AD value acquisition information and the voltage value of the electric detonator, and acquiring the voltage value information of the electric detonator.
4. The simulated test method for fire suppression apparatus detection as recited in claim 2, wherein said accumulated energy value determining step comprises:
setting an accumulated time: setting the accumulation time to be 100ms, and acquiring accumulation time setting information;
setting the disconnection energy threshold of the electric detonator: and setting the disconnection energy threshold of the electric detonator to be 108 mJ, and obtaining the disconnection energy threshold parameter of the electric detonator.
5. A simulation test system suitable for fire suppression device detection, comprising:
the timed interruption time setting module: setting the timed interruption time to a time value less than 1ms, and acquiring the set result information of the timed interruption time;
the electric detonator voltage value acquisition module: setting result information according to the timing interruption time, and acquiring an AD value of the driving voltage of the electric detonator in each interruption time to acquire AD value acquisition information;
acquiring information according to the AD value to acquire voltage value information of the electric detonator;
the energy value of the electric detonator obtains the module: acquiring the energy value of the electric detonator passing through the electric detonator in unit time according to the voltage value information of the electric detonator and the resistance value parameter of the electric detonator, and acquiring the energy value information of the electric detonator in unit time;
an accumulated time setting module: setting accumulation time, and acquiring accumulation time setting information;
an accumulated energy value judgment module: acquiring accumulated energy value information of the simulated electric detonator according to the accumulated time setting information, the electric detonator energy value information in unit time and the electric detonator disconnection energy threshold parameter;
selecting a control module: comparing the accumulated energy value in the set accumulation time with the electric detonator disconnection energy threshold value to obtain the direct electric detonator disconnection control information or zero clearing control information;
an accumulated energy value recalculation module: according to the zero clearing control information, repeatedly executing the accumulated energy value judgment module;
the simulation test result acquisition module: directly disconnecting control information according to the simulated electric detonator to obtain simulated test result information of the fire extinguishing device;
the direct disconnection control information of the electric detonator is used for guiding the direct disconnection behavior of the electric detonator;
and the zero clearing control information guides zero clearing action of the accumulated energy value calculation.
6. The simulation test system suitable for fire extinguishing apparatus detection according to claim 5, wherein the electric detonator voltage value obtaining module comprises:
the single chip microcomputer selection module: and selecting a singlechip with the AD resolution of 12 bits, acquiring the AD value of the driving voltage of the electric detonator within each interrupt time, wherein the AD value is less than or equal to 4096, and acquiring AD value acquisition information and AD value maximum threshold information.
7. The simulation test system suitable for fire extinguishing apparatus detection according to claim 6, wherein the electric detonator voltage value obtaining module further comprises:
the electric detonator voltage value calculation formula construction module comprises: constructing a voltage division circuit formula according to the maximum threshold value information of the AD value, and acquiring the voltage value calculation model information of the electric detonator; the voltage division circuit is constructed according to the following formula:
wherein U is a driving voltage value, U1The voltage value is the voltage value of the electric detonator;
and calculating model information according to the AD value acquisition information and the voltage value of the electric detonator, and acquiring the voltage value information of the electric detonator.
8. The simulated test system suitable for fire suppression apparatus detection as claimed in claim 5, wherein said accumulated energy value determination module comprises:
an accumulated time setting module: setting the accumulation time to be 100ms, and acquiring accumulation time setting information;
the electric detonator disconnection energy threshold setting module: and setting the disconnection energy threshold of the electric detonator to be 108 mJ, and obtaining the disconnection energy threshold parameter of the electric detonator.
9. A computer-readable storage medium storing a computer program, characterized in that the computer program, when being executed by a processor, carries out the steps of the simulation test method for fire-extinguishing device detection of any one of claims 1 to 4.
10. A simulation test apparatus suitable for fire suppression device detection, comprising: a controller;
the controller comprises a computer readable storage medium of claim 9 having a computer program stored thereon, which when executed by a processor implements the steps of the simulation test method for fire suppression apparatus detection of any one of claims 1 to 4; alternatively, the controller comprises a simulated test system suitable for fire suppression apparatus detection as claimed in any one of claims 5 to 8.
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CN111987758A (en) * | 2020-07-08 | 2020-11-24 | 中国兵器装备集团上海电控研究所 | Charging and current-limiting protection circuit |
CN112185232A (en) * | 2020-09-30 | 2021-01-05 | 中国兵器装备集团上海电控研究所 | Fire extinguishing bottle simulation device and method |
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