CN210400660U - Exposed bridge wire optical fiber temperature measurement and calibration system of stable and constant electric explosion device - Google Patents
Exposed bridge wire optical fiber temperature measurement and calibration system of stable and constant electric explosion device Download PDFInfo
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- CN210400660U CN210400660U CN201921171410.7U CN201921171410U CN210400660U CN 210400660 U CN210400660 U CN 210400660U CN 201921171410 U CN201921171410 U CN 201921171410U CN 210400660 U CN210400660 U CN 210400660U
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Abstract
The utility model discloses a bare bridge wire optical fiber temperature measurement calibration system of a steady lower electric explosion device, which comprises an electric explosion device; the electric explosion device comprises a lead, a bridge wire arranged in the lead and a medicament wrapped around the bridge wire; the exposed bridgewire after the medicament is removed is respectively electrically connected with the optical fiber temperature measurement system and the optical fiber temperature measurement calibration system; the optical fiber temperature measuring system comprises a temperature measuring sensor arranged close to the exposed bridge wire, an optical fiber temperature measuring system host connected with the temperature measuring sensor in a communication way, and a control test system electrically connected with the optical fiber temperature measuring system host; the optical fiber temperature measurement calibration system comprises a trackable direct current stable power supply for providing stable current for the bare bridge wire; the utility model discloses a bare bridging filament optic fibre temperature measurement calibration system of electric explosion device under steady, calibration electric explosion device realizes the effective prediction of the temperature rise of naked bridge under the different injection currents to bridging filament temperature rise measuring result's influence at different injection current conditions.
Description
Technical Field
The utility model relates to a steady electric explosion device exposes bridging fiber temperature measurement calibration system down belongs to military equipment technical field.
Background
The electric explosion device is commonly used for igniting gunpowder and detonating explosives, can also be used as a small-sized driving device for quickly opening a valve, relieving safety, separating rockets and the like, and can be widely applied to military projects such as conventional weapons and ammunition, missiles, nuclear weapons, aerospace systems and the like; the energy source is the most sensitive initial energy source for initiation and ignition, the position and the action of the energy source in a weapon system are determined by the functional initiatives and the action sensitivity of the energy source, and the safety and the reliability of the energy source directly influence the safety and the reliability of the weapon system. The high safety and the high reliability of weapon equipment require that the electric explosion device can ensure the safety under the action of strong-field electromagnetic radiation, the electromagnetic radiation sensitivity of the electric explosion device is closely related to the actual installation and application state thereof and is limited by the equipment linearity and the radiation field intensity, the effect test of the actual installation electric explosion device by adopting the traditional full-level electromagnetic radiation method meets the technical bottleneck in the aspect of electromagnetic environment simulation, and the equivalent test method is produced in accordance with the operation; although the technology for testing and evaluating the electromagnetic radiation safety of the electric explosion device by adopting the method for measuring bridge wire induced current, voltage or power of the electric explosion device is mature, the upper limit of the test frequency is difficult to effectively expand due to the influence of current standing wave distribution and skin effect, and the accuracy is difficult to ensure in a microwave frequency band; although the upper limit of the applicable frequency of the differential mode current injection method can reach 18GHz, the differential mode injection device has large volume and is a coaxial interface, and is difficult to be used for the electromagnetic radiation safety actual installation test of the electric explosion device; the optical fiber temperature measurement method accords with the ignition mechanism of a glowing bridge wire type electric explosion device, the ignition temperature rise of the bridge wire is almost unrelated to the radiation frequency of electromagnetic waves, and the measurement of the bridge wire temperature rise is an effective method for solving the problem of full-band electromagnetic radiation safety test evaluation of the electric explosion device; how to determine the influence rule of different injection currents on the bridge wire temperature rise measurement value of the electric explosion device, establish a bridge wire temperature rise calibration model, and provide a strong-field electromagnetic radiation effect test evaluation method of the electric explosion device, which is a key problem to be solved urgently.
SUMMERY OF THE UTILITY MODEL
For solving the problem, the utility model provides a bare bridging filament optic fibre temperature measurement calbiration system of electric explosion device under steady, the effective prediction of temperature rise is sent out to the naked bridge under the different injection currents in the influence of different injection current conditions to bridging filament temperature rise measuring result to the electric explosion device of calibration.
The utility model discloses a temperature measurement and calibration system for exposed bridge wire optical fiber of a steady lower electric explosion device, which comprises an electric explosion device; the electric explosion device comprises a lead, a bridge wire arranged in the lead and a medicament wrapped around the bridge wire; the exposed bridgewire after the medicament is removed is respectively electrically connected with the optical fiber temperature measurement system and the optical fiber temperature measurement calibration system;
the optical fiber temperature measuring system comprises a temperature measuring sensor arranged close to the exposed bridge wire, an optical fiber temperature measuring system host connected with the temperature measuring sensor in a communication way, and a control test system electrically connected with the optical fiber temperature measuring system host; the optical fiber temperature measurement system host is provided with an optical fiber data acquisition module; the temperature measuring sensor is connected with the optical fiber temperature measuring system host through an optical fiber and an optical fiber data acquisition module;
the optical fiber temperature measurement calibration system comprises a trackable direct current stable power supply for providing stable current for the bare bridge wire, a digital multimeter electrically connected with a constant current output end of the trackable direct current stable power supply, and two timers connected with the trackable direct current stable power supply in parallel; the power end of each of the two timers is electrically connected with the constant voltage output end of the trackable direct current stabilized power supply; and electric control ends of the two timers are respectively connected with the bridge wire in parallel to a constant current output end of the trackable direct current stable power supply.
Furthermore, the trackable direct current stable power supply is a double-circuit constant voltage and constant current power supply.
Furthermore, the two timers are time relays, one timer is a normally closed relay with the timing time of 2S, and the other timer is a normally open relay with the timing time of 12S.
Furthermore, the coils of the normally closed relay and the normally open relay are respectively and electrically connected with the constant voltage output end of the trackable direct current stabilized power supply; the normally closed relay is in a closed state in a normal state, and the normally closed relay is set to work for 2 seconds and then disconnected; the normally open relay is in a disconnected state in a normal state, and the normally open relay is closed after setting work of 12S is carried out through timing setting on the relay; the trackable direct-current stabilized power supply provides 24V working voltage for the normally open relay and the normally closed relay independently; the normally open relay closing switch (normally open contact of the normally open relay), the normally closed relay opening switch (normally closed contact of the normally closed relay) and the exposed bridge wire are connected in parallel by a lead; one path of voltage output of the direct current stabilized power supply can be tracked to provide 24V working voltage for a normally open relay and a normally closed relay, and the other path of current output directly acts on two ends of a normally open relay closing switch, a normally closed relay opening switch and an exposed bridge wire which are connected in parallel, so that the current injection control of the exposed bridge wire is realized; the two paths of signals can be directly opened or closed at the same time through the trackable direct current stabilized power supply; when the normally closed relay starts to work, the normally closed relay is in a closed state, current directly flows through the closed switch of the normally closed relay, and no current flows through other parallel circuits; after 2S, the normally closed relay closes the switch to be disconnected, and at the moment, current flows through the exposed bridge wire, so that current injection of the exposed bridge wire is realized; 12S, the normally open relay disconnecting switch is closed, current flows through the normally open relay disconnecting switch, and no current flows through other parallel circuits; the control of the exposed bridge wire current injection is realized through a normally closed relay and a normally open relay.
The utility model discloses a prediction method of exposed bridging filament optic fibre temperature measurement calibration system of electric explosion device under steady, including following step:
the method comprises the following steps: an optical fiber temperature measuring system and two timers can be directly trackedConstructing a calibration system of the bare bridge wire optical fiber temperature measurement system by using a current stabilization power supply and a digital multimeter; specifically, a trackable direct-current stable power supply is adopted, one output provides working voltage for two timers, and the other output provides stable current for an exposed bridge wire; one of the two timers is a normally closed relay with the time delay set to be 2S, and the other timer is a normally open relay with the time delay set to be 12S, and both the normally closed relays and the normally open relays are connected in parallel to a trackable direct-current stable power supply for supplying current to the exposed bridge wire; measuring the magnitude of a stable current provided by a trackable direct-current stable power supply for the bare bridge wire by using a digital multimeter; at the time of the test, at ambient temperature T0Next, carrying out a steady current injection test on the electric explosion device, measuring a trackable direct-current stable power supply by using a digital multimeter to provide stable current for the exposed bridge wire, stopping current output when the current reaches 20mA, replacing the digital multimeter by using the exposed bridge wire, namely detaching the digital multimeter, replacing the digital multimeter by using the exposed bridge wire, starting to inject the current with the size of 20mA into the exposed bridge wire after the normally closed relay is disconnected in 2S, starting to record the temperature of the exposed bridge wire tested by an optical fiber temperature measurement system, closing the normally open relay after 12S, and stopping injecting the current into the exposed bridge wire at the moment; setting the current step as 10mA, recording the corresponding test value of the optical fiber temperature measuring system when different currents are injected into the bare bridge wire according to the steps, and stopping the test when the injected current reaches 100 mA; the ignition excitation parameters in the current injection test comprise the amplitude of current, the opening of a normally closed relay and the closing of a normally open relay;
step two: a calibration system is set up, the bare bridgewire is assimilated with the room temperature environment for 4 hours, and the environment temperature T is tested when current is not injected into the bridgewire0The temperature of the lower exposed bridge wire is the reference temperature of the bridge wire; specifically, get rid of the medicament of the interior parcel bridgewire of electric explosion device, place temperature sensor near the bridgewire to being connected temperature sensor and the experimental configuration of optic fibre temperature measurement, through optical fiber transmission to optic fibre temperature measurement system host computer with bridgewire temperature measurement signal, install optic fibre data acquisition module on the optic fibre temperature measurement system host computer, optic fibre temperature measurement system host computer electricity is connected to control test system, keeps other experimental conditions unchangeable, the exposed bridgewire temperature that corresponds when the test was injected into different electric currentsLifting; selecting bare bridge wire injection current starting at 10mA, the maximum value at 100mA and stepping at 10mA to carry out calibration of the optical fiber temperature measurement system, determining the rule of influence of the injection current on the temperature measurement result, and simultaneously controlling the test environment temperature in the step two to be the same as the test environment temperature in the step one;
step three: at the same ambient temperature T0And then, repeating the first step and the second step under the condition of injecting different currents into the bridge wire to obtain the exposed bridge wire ignition temperature TiAnd injection current IiA relationship model between; specifically, according to the exposed bridge wire temperature rise principle of the electric explosion device, the exposed bridge wire temperature T is establishediAnd ambient temperature T0Injection current IiThe relationship model can obtain the following results according to the direct proportional relationship between the temperature rise of the bridge wire and the square value of the input current:
Ti-T0∝Ii 2,(1)
in the formula, k1Is a constant;
in order to determine the relationship between the temperature rise of the exposed bridge wire and the injected current, experimental research needs to be carried out under the injection of at least 3 different currents, and a relationship model between the three can be established; using different injection currents Ii+1Lower measured bare bridge ignition temperature Ti+1Obtaining a set of ambient temperatures T0Bare bridge temperature Ti+1Corresponding current I ofi+1Relational data; from this set of data, in conjunction with equation (2), the quantitative solution determines the constant k1Thereby establishing the bare bridge wire ignition temperature TiAnd ambient temperature T0Corresponding current IiThe relationship between them is as follows:
step four: utilizing the exposed bridge wire ignition temperature T obtained in the step threeiAnd injection current IiModel of relationship between, implementationThe naked bridge ignition temperature rise and the effective prediction under different injected currents are carried out; in particular, according to equation (3), given the other arbitrary injection current I at which the device subject to electrical explosion is locatedi+1Calculating the corresponding bare bridge wire temperature Ti+1Temperature rise at ignition of Ti+1-T0Therefore, the effective prediction of the naked bridge ignition temperature rise under different injected currents is realized, and the engineering practicability of the test method is improved.
The utility model discloses a prior art compares, the utility model discloses a bare bridging filament optic fibre temperature measurement calibration system of electric explosion device under steady realizes the bare bridge temperature rise of initiating a fire and injects effective prediction under the different electric currents, improves and uses the bare bridge temperature rise to judge the effective prediction of the bare bridging filament injection current of electric explosion device under steady as the foundation, provides reliable foundation for carrying out strong electromagnetic radiation safety margin evaluation of weaponry.
Drawings
Fig. 1 is a schematic view of the overall structure of the present invention.
The parts in the drawings are marked as follows: the system comprises a normally closed relay, a normally open relay, a trackable direct current stable power supply, a 4-digital multimeter, a 5-temperature measurement sensor, a 6-bridge wire, a 7-optical fiber data acquisition module, an 8-optical fiber temperature measurement system host and a 9-control test system.
Detailed Description
The exposed bridge wire optical fiber temperature measurement calibration system of the steady lower electric explosion device shown in figure 1 comprises an electric explosion device; the electric explosion device comprises a lead, a bridge wire 6 arranged in the lead and a medicament wrapped around the bridge wire 6; the exposed bridge wire 6 after the medicament is removed is respectively electrically connected with the optical fiber temperature measurement system and the optical fiber temperature measurement calibration system;
the optical fiber temperature measuring system comprises a temperature measuring sensor 5 arranged close to the bare bridgewire 6, an optical fiber temperature measuring system host 8 in communication connection with the temperature measuring sensor 5, and a control test system 9 electrically connected with the optical fiber temperature measuring system host 8; the optical fiber temperature measurement system host 8 is provided with an optical fiber data acquisition module 7; the temperature measuring sensor 5 is connected with an optical fiber temperature measuring system host 8 through an optical fiber data acquisition module 7;
the optical fiber temperature measurement calibration system comprises a trackable direct current stable power supply 3 for providing stable current for a bare bridge wire, a digital multimeter 4 electrically connected with a constant current output end of the trackable direct current stable power supply 3, and two timers connected with the trackable direct current stable power supply 3 in parallel; the power end of each of the two timers is electrically connected with the constant voltage output end of the trackable direct current stabilized power supply 3; the electric control ends of the two timers are respectively connected with the bridge wire 6 in parallel to the constant current output end of the trackable direct current stable power supply 3.
The trackable direct current stable power supply 3 is a double-circuit constant voltage and constant current power supply.
The two timers are time relays, one timer is a normally closed relay 1 with the timing time of 2S, and the other timer is a normally open relay 2 with the timing time of 12S.
The coils of the normally closed relay 1 and the normally open relay 2 are respectively and electrically connected with the constant voltage output end of the trackable direct current stabilized power supply 3; and a normally closed contact of the normally closed relay 1 and a normally open contact of the normally open relay 2 are connected in parallel and then are electrically connected with a constant current output end of the trackable direct current stable power supply 3.
The utility model discloses a prediction method of exposed bridging filament optic fibre temperature measurement calibration system of electric explosion device under steady, including following step:
the method comprises the following steps: constructing a calibration system of the bare bridge fiber temperature measurement system by using the fiber temperature measurement system, two timers, a trackable direct-current stable power supply and a digital multimeter; specifically, a trackable direct-current stable power supply is adopted, one output provides working voltage for two timers, and the other output provides stable current for an exposed bridge wire; one of the two timers is a normally closed relay with the time delay set to be 2S, and the other timer is a normally open relay with the time delay set to be 12S, and both the normally closed relays and the normally open relays are connected in parallel to a trackable direct-current stable power supply for supplying current to the exposed bridge wire; measuring the magnitude of a stable current provided by a trackable direct-current stable power supply for the bare bridge wire by using a digital multimeter; at the time of the test, at ambient temperature T0Then, a constant current injection test is carried out on the electric explosion device, and a digital multimeter is used for measuring the condition that the trackable direct current stable power supply is exposedThe bridge wire provides stable current, when the current reaches 20mA, the current output is stopped, the digital multimeter is replaced by the exposed bridge wire, when the normally closed relay is disconnected in 2S, the current with the size of 20mA is injected into the exposed bridge wire, the temperature of the exposed bridge wire tested by the optical fiber temperature measuring system is recorded, after 12S, the normally open relay is closed, and at the moment, the current injection into the exposed bridge wire is stopped; setting the current step as 10mA, recording the corresponding test value of the optical fiber temperature measuring system when different currents are injected into the bare bridge wire according to the steps, and stopping the test when the injected current reaches 100 mA; the ignition excitation parameters in the current injection test comprise the amplitude of current, the opening of a normally closed relay and the closing of a normally open relay;
step two: a calibration system is set up, the bare bridgewire is assimilated with the room temperature environment for 4 hours, and the environment temperature T is tested when current is not injected into the bridgewire0The temperature of the lower exposed bridge wire is the reference temperature of the bridge wire; specifically, removing a medicament wrapping a bridge wire in an electric explosion device, placing a temperature measuring sensor close to the bridge wire, connecting the temperature measuring sensor with an optical fiber temperature measuring test configuration, transmitting a bridge wire temperature measuring signal to an optical fiber temperature measuring system host through an optical fiber, installing an optical fiber data acquisition module on the optical fiber temperature measuring system host, electrically connecting the optical fiber temperature measuring system host to a control test system, keeping other experimental conditions unchanged, and testing the temperature rise of the corresponding exposed bridge wire when injecting different currents; selecting bare bridge wire injection current starting at 10mA, the maximum value at 100mA and stepping at 10mA to carry out calibration of the optical fiber temperature measurement system, determining the rule of influence of the injection current on the temperature measurement result, and controlling the test environment temperature in the second step to be the same as the test environment temperature in the first step;
step three: at the same ambient temperature T0And then, repeating the first step and the second step under the condition of injecting different currents into the bridge wire to obtain the exposed bridge wire ignition temperature TiAnd injection current IiA relationship model between; specifically, according to the exposed bridge wire temperature rise principle of the electric explosion device, the exposed bridge wire temperature T is establishediAnd ambient temperature T0Injection current IiThe relationship model can obtain the following results according to the direct proportional relationship between the temperature rise of the bridge wire and the square value of the input current:
Ti-T0∝Ii 2, (1)
in the formula, k1Is a constant;
in order to determine the relationship between the temperature rise of the exposed bridge wire and the injected current, experimental research needs to be carried out under the injection of at least 3 different currents, and a relationship model between the three can be established; using different injection currents Ii+1Lower measured bare bridge ignition temperature Ti+1Obtaining a set of ambient temperatures T0Bare bridge temperature Ti+1Corresponding current I ofi+1Relational data; from this set of data, in conjunction with equation (2), the quantitative solution determines the constant k1Thereby establishing the bare bridge wire ignition temperature TiAnd ambient temperature T0Corresponding current IiThe relationship between them is as follows:
step four: utilizing the exposed bridge wire ignition temperature T obtained in the step threeiAnd injection current IiThe relationship model realizes the effective prediction of the naked bridge ignition temperature rise and the injection of different currents; in particular, according to equation (3), given the other arbitrary injection current I at which the device subject to electrical explosion is locatedi+1Calculating the corresponding bare bridge wire temperature Ti+1Temperature rise at ignition of Ti+1-T0Therefore, the effective prediction of the naked bridge ignition temperature rise under different injected currents is realized, and the engineering practicability of the test method is improved.
The utility model discloses a bare bridge wire optical fiber temperature measurement calibration system of an electric explosion device under steady state, starting from the ignition mechanism of a glowing bridge wire type electric explosion device, the bare bridge wire optical fiber temperature measurement system calibration system is constructed by adopting an optical fiber temperature measurement system, two timers, a double-circuit constant voltage and constant current power supply and a digital multimeter; a calibration system is set up, and the bare bridgewire is assimilated with the room temperature environment for 4 hours instead ofWhen the bridge wire injects current, the test environment temperature T0The temperature of the lower exposed bridge wire is the reference temperature of the bridge wire; at the same ambient temperature T0And then, repeating the first step and the second step under the condition of injecting different currents into the bridge wire to obtain the exposed bridge wire ignition temperature TiAnd injection current IiA relationship model between; utilizing the exposed bridge wire ignition temperature T obtained in the step threeiAnd injection current IiThe relation model realizes effective prediction of the naked bridge ignition temperature rise and the injection of different currents, improves effective prediction of the naked bridge wire injection current of the electric explosion device under stable judgment by taking the naked bridge temperature rise as a basis, and provides a reliable basis for carrying out strong-field electromagnetic radiation safety margin evaluation of weaponry.
The above-mentioned embodiment is only the preferred embodiment of the present invention, so all the equivalent changes or modifications made by the structure, features and principles of the present invention are included in the claims of the present invention.
Claims (4)
1. A temperature measurement and calibration system for bare bridge wire optical fiber of an electric explosion device under steady state comprises the electric explosion device; the electric explosion device comprises a lead, a bridge wire arranged in the lead and a medicament wrapped around the bridge wire; the method is characterized in that: the exposed bridgewire after the medicament is removed is respectively electrically connected with the optical fiber temperature measurement system and the optical fiber temperature measurement calibration system;
the optical fiber temperature measuring system comprises a temperature measuring sensor arranged close to the exposed bridge wire, an optical fiber temperature measuring system host connected with the temperature measuring sensor in a communication way, and a control test system electrically connected with the optical fiber temperature measuring system host; the optical fiber temperature measurement system host is provided with an optical fiber data acquisition module; the temperature measuring sensor is connected with the optical fiber temperature measuring system host through an optical fiber and an optical fiber data acquisition module;
the optical fiber temperature measurement calibration system comprises a trackable direct current stable power supply for providing stable current for the bare bridge wire, a digital multimeter electrically connected with a constant current output end of the trackable direct current stable power supply, and two timers connected with the trackable direct current stable power supply in parallel; the power end of each of the two timers is electrically connected with the constant voltage output end of the trackable direct current stabilized power supply; and electric control ends of the two timers are respectively connected with the bridge wire in parallel to a constant current output end of the trackable direct current stable power supply.
2. The exposed bridge wire optical fiber temperature measurement and calibration system of the steady lower electric explosion device according to claim 1, which is characterized in that: the trackable direct current stable power supply is a double-circuit constant voltage and constant current power supply.
3. The exposed bridge wire optical fiber temperature measurement and calibration system of the steady lower electric explosion device according to claim 1, which is characterized in that: the two timers are time relays, one timer is a normally closed relay with the delay time of 2S, and the other timer is a normally open relay with the delay time of 12S.
4. The exposed bridge wire optical fiber temperature measurement and calibration system of the steady lower electric explosion device according to claim 3, characterized in that: the coils of the normally closed relay and the normally open relay are respectively and electrically connected with the constant voltage output end of the trackable direct current stabilized power supply; and a normally closed contact of the normally closed relay and a normally open contact of the normally open relay are electrically connected with a constant current output end of the trackable direct current stable power supply after being connected in parallel.
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Cited By (1)
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CN110567613A (en) * | 2019-07-24 | 2019-12-13 | 中国人民解放军陆军工程大学 | Exposed bridge wire optical fiber temperature measurement calibration system and prediction method for electric explosion device under steady state |
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CN110567613A (en) * | 2019-07-24 | 2019-12-13 | 中国人民解放军陆军工程大学 | Exposed bridge wire optical fiber temperature measurement calibration system and prediction method for electric explosion device under steady state |
CN110567613B (en) * | 2019-07-24 | 2024-07-23 | 中国人民解放军陆军工程大学 | Temperature measurement calibration system and prediction method for bare bridge mercerized fibers of stable and constant electric explosion device |
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