Patent Description:
Traditional fire composite detectors are mostly temperature and smoke composite detectors, which detect a signal only after a fire and/or smoke occurs, and there is a possibility that a serious safety accident is caused due to the fact that a detection signal lags behind the ejection delay of a fire-fighting inhibitor.

According to the data released by lithium battery manufacturers, the combustible gas generated by emitting from the valve during the thermal run-away control of the lithium battery mainly comprises hydrogen, carbon monoxide, VOC (Volatile Organic Compounds carbon dioxide, nitrogen, methane, butane, ethylene, etc. , and VOC is a volatile organic compound. At present, composite detectors for monitoring combustible gas, temperature and smoke have emerged on the market. As an important component of fire fighting system of the energy storage, they are generally installed in a battery pack, a power cabinet and a container, mainly used for detecting thermal runaway of a lithium battery. By monitoring the changes in carbon monoxide, VOC, hydrogen, temperature and smoke in the area, the composite detectors can make an accurate detection and send an alarm in the early stages of thermal runaway of lithium batteries. The staff can handle the fire before it occurs to avoid safety accidents.

The composite detector needs to be detected before being put into use to ensure its normal function and accurate accuracy. However, with regard to the detection of a compound detector, there is no standard detection method at present, and a simple qualitative detection method is commonly used. Without a quantitative calibration detection method, the detection result will be inaccurate, resulting in that composite detectors with a relatively large accuracy error flows into the market and brings a potential safety hazard to energy storage systems.

<CIT> discloses a system for evaluating a composite detector, the system comprising: a box, a smoke generator, a standard gas storage tank wherein the box is sealed, and the composite detector; wherein the smoke generator and the standard gas storage tank are arranged outside the box, whereby the smoke generator and the standard gas storage tank are fluidically connected to the box, the smoke generator and the standard gas storage tank being used to simulate a battery thermal runaway environment within the box; and a computer for comparing second detection data obtained from the composite detector arranged in the box with first data so as to obtain a qualitative and quantitative analysis of detection accuracy of the composite detector. The main problems with existing technology comprise: (<NUM>) For example, <CIT> provides a method and system for on-site detection and calibration of point-type smoke and temperature fire detectors, but it is unable to detect composite detectors; <CIT> proposes a detection instrument for detecting fire alarm detectors, which is used for detecting smoke, temperature, or flame related alarm detectors, but cannot evaluate composite detectors. (<NUM>) The detection methods of the prior art are too rough and the detection instruments are relatively simple, which can only conduct simple qualitative analysis to preliminarily determine whether the function of the composite detector is normal, but cannot quantitatively detect the detector, which has great limitations. (<NUM>) At present, the detection method of smoke fire detectors mainly adopts the traditional claves-adding cigarette form. The burning of the claves produces soot, polycyclic aromatic hydrocarbons, volatile organic compounds, etc. After cigarette ignition, a large amount of tar, carbon monoxide, nicotine, soot, and irritating smoke can be released. Soot and tar will be adsorbed on the components, PCB (Printed Circuit Board) boards, and wiring harness connectors inside the detector, which may cause aging, pollution, and poor contact of the detector, resulting in false alarms and missed alarms of the composite probes. (<NUM>) The power level, gear intensity, and air vent direction of the hot air gun can all affect the temperature of the monitoring points inside the sealed box. There are too many variable factors, and the measured temperature data is inaccurate.

In the prior art, qualitative detection is generally performed on a composite detector. For example, as shown in <FIG>, roughly simulating an environment of thermal runaway of a battery. In a sealed box body, insert a lit incense stick or cigarette into a smoke gun, use a fan to blow smoke and carbon monoxide into the sealed box, use alcohol to simulate VOC components, and turn on the hot air gun to increase the temperature inside the sealed box. During the attempt to simulate the thermal runaway environment, if the detection indicators (carbon monoxide, smoke, VOC, temperature) exactly reach the alarm threshold, the composite detector will send out corresponding alarm signals to achieve the detecting purpose.

The composite detector, relay module and upper computer communicate with each other through CAN (Controller Area Network), and when a lithium battery thermal runaway environment is simulated in a sealed box, the upper computer displays the detected gas concentration, smoke concentration, temperature and other indicators. This method is only suitable for qualitative detection of the detector.

The purpose of the present disclosure is to provide a system and method for evaluating a composite detector, which can scientifically determine whether the sensitivity, detection accuracy and functionality of the composite detector meet the technical requirements.

In order to achieve the above-mentioned purpose, the present disclosure provides the following technical solutions.

A system for evaluating a composite detector, the system comprising: a constant-temperature box, a smoke generator, a standard gas storage tank, a gas collection device and a laser Raman spectroscopy analyzer, wherein the constant-temperature box is sealed, and both the composite detector and the gas collection device are arranged in the constant-temperature box; wherein the smoke generator, the standard gas storage tank and the laser Raman spectroscopy analyzer are all arranged outside the constant-temperature box, whereby the smoke generator and the standard gas storage tank are fluidically connected to the box, the smoke generator and the standard gas storage tank being used to simulate a battery thermal runaway environment within the box; wherein the laser Raman spectroscopy analyzer is fluidically connected to the gas collection device for receiving gas from the gas collection device and for analysing the gas to obtain first detection data of the gas; and a computer for comparing the first detection data with second detection data obtained from a composite detector arranged in the constant-temperature box, so as to obtain a qualitative and quantitative analysis of detection accuracy of the composite detector.

Further, the system may comprise a data information collection and transmission device and an upper computer, wherein the laser Raman spectroscopy analyzer is connected to the upper computer, and the composite detector is connected to the upper computer through the data information collection and transmission device; the upper computer compares and analyzes the first detection data with the second detection data.

Further, in the system, the standard gas storage tank may comprise a hydrogen storage tank, a carbon monoxide storage tank and a VOC storage tank.

Further, in the system, detection accuracy of the laser Raman spectroscopy analyzer may be <NUM>% FS.

In another aspect, the present disclosure provides a method for evaluating a composite detector utilizing the aforementioned system as set out in the appended set of claims. The method may further comprise the following steps of:.

Further, in the method, the predetermined time in S3 is <NUM> minute to <NUM> minutes.

Further, in the method, the predetermined time in S4 is <NUM> minutes to <NUM> minutes.

Further, in the method, the predetermined time in S5 is <NUM> minutes to <NUM> minutes.

Further, in the method, the first detection data comprises gas component and concentration changes of smoke, hydrogen, VOC and carbon monoxide in S5; the second detection data comprises temperature inside the constant temperature chamber, and gas component and concentration changes of smoke, hydrogen, VOC and carbon monoxide.

Further, in the method, preheating the laser Raman spectroscopy analyzer for <NUM> minutes in S1, and maintaining a constant temperature for <NUM> minutes in S2.

Analysis shows that the present disclosure discloses a system and method for evaluating a composite detector, provides a qualitative and quantitative method for evaluating composite detectors (carbon monoxide, hydrogen, VOC, temperature, smoke), and uses standard gas generators or standard gas storage tanks to simulate an environment of battery thermal runaway. By comparing the first detection data with the second detection data synchronously to scientifically determine whether the sensitivity, detection accuracy, and functionality of the composite detector meet technical requirements. The method is compliant and more suitable for standardized promotion and use, and the accuracy of the detection instrument meets the needs of quantitative detection and calibration. In addition to the gas component, temperature and smoke to be detected, it can eliminate the interference of other impurities (such as soot, polycyclic aromatic hydrocarbons, tar or nicotine), reduce the dependent variable, and do not cause pollution and aging effects on the composite detector, so the method is more scientific. By keeping the temperature value inside the sealed box constant and consistent with the set temperature value, scientifically and reasonably control the temperature of the environment to be detected, and the detection results are more informative. Based on the various characteristic gases generated during the thermal runaway of lithium batteries, this system can select different standard gases for the gas components to be detected, such as carbon monoxide standard gas, hydrogen standard gas, VOC, carbon dioxide standard gas, and alkane standard gas, which can meet the calibration requirements of composite detectors with multiple gas components.

The accompanying drawings forming a part of the present disclosure are used to provide further understanding of the present disclosure. The schematic embodiments and explanations of the present disclosure are used to explain the present disclosure and do not constitute an improper limitation of the present disclosure.

An embodiment of the present disclosure will now be described by way of example only and with reference to the accompanying drawings. Those skilled in the art will be aware that modifications and variations can be made in the present disclosure without departing from the scope of the present invention as set out in the appended set of claims. For example, features shown or described as part of one embodiment may be used in another embodiment to generate another embodiment. Therefore, it is expected that the present disclosure comprises such modifications and variations within the scope of the accompanying claims and their equivalents.

In the description of the present disclosure, the terms "transverse", "longitudinal", "up", "bottom", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", etc. indicate orientation or positional relationships based on the orientation or positional relationships shown in the accompanying drawings, only for the convenience of describing the present disclosure and not for requiring the present disclosure to be constructed and operated in a specific orientation, and thus it cannot be understood as a limitation of the present disclosure. The terms "link", "connect", and "set" used in the present disclosure should be broadly understood, for example, they can be fixed connections or detachable connections; it can be directly connected or indirectly connected through intermediate components; and it can be a wired electrical connection, a wireless connection, or a wireless communication signal connection. For ordinary technical personnel in this field, the specific meanings of the above terms can be understood based on specific circumstances.

As shown in <FIG>, according to an embodiment of the present disclosure, a system for evaluating a composite detector, which comprises a constant-temperature box, a smoke generator, a standard gas storage tank, a gas collection device and a laser Raman spectroscopy analyzer; wherein the constant-temperature box is sealed, and both the composite detector and the gas collection device are arranged in the constant-temperature box; the smoke generator, the standard gas storage tank and the laser Raman spectroscopy analyzer are all arranged outside the constant-temperature box; and the constant-temperature box, the smoke generator, and the standard gas storage tank are used to simulate a battery thermal runaway environment; the laser Raman spectroscopy analyzer receives gas from the gas collection device for detection and obtains gas detection data, the detection data is called the first detection data. The composite detector can detect the detection data, the detection data detected by the composite detector is called the second detection data, by comparing and analyzing the first detection data with the second detection data, the composite detector is calibrated, and a qualitative and quantitative detection result is obtained.

Preferably, the system further comprises a data information collection and transmission device and an upper computer, wherein the laser Raman spectroscopy analyzer is connected to the upper computer, the composite detector is connected to the upper computer through the data information collection and transmission device; and the upper computer compares and analyzes the first detection data with the second detection data.

Preferably, the standard gas storage tank comprises a hydrogen storage tank, a carbon monoxide storage tank and a VOC storage tank.

Preferably, detection accuracy of the laser Raman spectroscopy analyzer is <NUM>% FS.

The present disclosure provides a system for evaluating a composite detector, which can perform a qualitative and quantitative detection for a composite detector. The used system comprises a laser Raman spectroscopy analyzer, a hydrogen storage tank, a carbon monoxide storage tank, a VOC storage tank, a smoke generator, a constant-temperature box, a composite detector, a data information collection and transmission device and an upper computer and so on. The schematic diagram of the connection is shown in <FIG>.

The laser Raman spectroscopy analyzer can perform qualitative and quantitative analysis of the molecular composition, structure, and relative content, such as solid, liquid and gaseous substances. The laser Raman spectroscopy analyzer is mainly used in natural gas analysis, biomass gas analysis, gas analysis of transformer oil fault, ethylene cracking furnace and other application scenarios. The advantages of the laser Raman spectroscopy analyzer are that it can monitor gas concentration in real-time online with fast detection speed, and can complete the analysis and measurement of all gases in <NUM> seconds. It can measure multiple components, especially for measuring the types of different hydrocarbons; the detection accuracy can reach up to <NUM>% FS (FS refers to Full Scale).

The present disclosure further discloses a method for evaluating a composite detector utilizing the system for evaluating the composite detector, wherein the method comprises the following steps of:.

In S2, maintain a constant temperature for <NUM> minutes to ensure that the temperature inside the box has reached the set temperature and remains stable before detecting. The constant temperature for <NUM> minutes is sufficient to stabilize the set temperature value.

S3: turning on the smoke generator and controlling a smoke concentration to reach a calibration value within a predetermined time, and turning off the smoke generator when the smoke concentration reaches the calibration value.

In S3, the predetermined time is the time range within which the smoke concentration produced by the smoke generator reaches the calibration value, approximately <NUM> minute to <NUM> minutes, to ensure efficiency and data accuracy. The calibration value refers to the smoke concentration reaching the alarm threshold of the composite detector. For example, when the smoke value reaches <NUM>. 5db/m, the composite detector emits a first level alarm, and when the smoke value reaches <NUM>. 2db/m, the composite detector emits a second level alarm. The alarm thresholds of different models of composite detectors may vary and are not fixed values, so the calibration values during detection should be determined based on the specifications of the composite detector.

S4: turning on the standard gas storage tanks, when the standard gas storage tank can comprise a VOC storage tank, a hydrogen storage tank, and a carbon monoxide storage tank, etc., then the VOC storage tank, hydrogen storage tank and carbon monoxide storage tank can be turned on successively in S4, the concentrations of VOC, hydrogen and carbon monoxide are controlled to reach the calibration value within a predetermined time, and when the concentrations of VOC, hydrogen and carbon monoxide reach the calibration value, the corresponding VOC storage tank, hydrogen storage tank, and carbon monoxide storage tank is turned off.

In S4, the predetermined time refers to the time range within which the concentrations of VOC, hydrogen, and carbon monoxide produced by the standard gas storage tank reach their respective calibration values. The entire process takes about <NUM> minutes to <NUM> minutes to ensure efficiency and data accuracy. The calibration value refers to the concentrations of VCO, hydrogen, and carbon monoxide reaching the alarm threshold of the composite detector. For example, when the VOC concentration reaches 200ppmor the hydrogen concentration reaches 125ppm or the carbon monoxide concentration reaches 50ppm, the composite detector emits a first level alarm. When the VOC concentration reaches 300ppm or the hydrogen concentration reaches 300ppm or the carbon monoxide concentration reaches 190ppm, the composite detector emits a second level alarm. The alarm thresholds of different models of composite detectors may vary and are not fixed values, so the calibration value during detection should be determined based on the specifications of the composite detector.

S5: by comparing and analyzing the first detection data with the second detection data, the composite detector is calibrated and a qualitative and quantitative detection result is obtained.

Specifically, when the system for evaluating the composite detector also comprises a data information collection and transmission device and an upper computer, the S5 specifically comprises the following steps of:.

S51: within a specified detection time, the first detection data and the second detection data being transmitted to the upper computer through the data information collection and transmission device.

In S51, the first detection data comprise gas components and concentration changes of smoke, hydrogen, VOC and carbon monoxide, and qualitative and quantitative analysis of the gas and VOC components. The second detection data of the composite detector comprises temperature inside the constant temperature chamber, gas components and concentration changes of smoke, hydrogen, VOC, and carbon monoxide.

S52: the upper computer comparing and analyzing the fist detection data with the second detection data; and
S53. performing qualitative and quantitative analysis of detection accuracy of the composite detector.

The schematic diagram of the steps is shown in <FIG>. By using the constant temperature box, the smoke generator, the standard gas storage tank, etc. to simulate the environment of battery thermal runaway, the sensitivity, detection accuracy, and functionality of the composite detector are scientifically judged by comparing and analyzing the first detection data with the second detection data.

The system and the method can be used to calibrate the composite detectors, give qualitative and quantitative detection results, calibrate the composite detectors, give quantitative data, and judge the detection accuracy and error of the composite detectors.

From the above description, it can be seen that the embodiments of the present disclosure achieve the following technical effects:
The present disclosure provides a qualitative and quantitative method and system for evaluating the composite detector (carbon monoxide, hydrogen, VOC, temperature, smoke), and uses a standard gas generator or standard gas storage tank to simulate the environment of battery thermal runaway, and by comparing the detection data (the first detection data) of professional equipment (laser Raman spectroscopy analyzer) with the second detection data synchronously to scientifically determine whether the sensitivity, detection accuracy, and functionality of the composite detector meet the technical requirements.

The detection is compliant and more suitable for standardized promotion and use, and the accuracy of the detection instrument meets the needs of quantitative detection and calibration.

In addition to the gas composition, temperature, and smoke to be detected, it can eliminate the interference of other impurities (soot, polycyclic aromatic hydrocarbons, tar, nicotine), reduce the dependent variable, and does not cause pollution and aging effects on the composite detector, so the method is more scientific.

By keep the temperature value inside the sealed box constant and consistent with the set temperature value, scientifically and reasonably control the temperature of the environment to be detected, and the detection results are more informative.

Based on the various characteristic gases generated during the thermal runaway of lithium batteries, this system can select different standard gases for the gas components to be detected, such as carbon monoxide standard gas, hydrogen standard gas, VOC, carbon dioxide standard gas, and alkane standard gas, which can meet the calibration requirements of composite detectors with multiple gas components.

Claim 1:
A system for evaluating a composite detector, the system comprising:
a constant-temperature box, a smoke generator, a standard gas storage tank, a gas collection device and a laser Raman spectroscopy analyzer, wherein
the constant-temperature box is sealed, and both the composite detector and the gas collection device are arranged in the constant-temperature box; wherein
the smoke generator, the standard gas storage tank and the laser Raman spectroscopy analyzer are all arranged outside the constant-temperature box, whereby the smoke generator and the standard gas storage tank are fluidically connected to the box, the smoke generator and the standard gas storage tank being used to simulate a battery thermal runaway environment within the box; wherein
the laser Raman spectroscopy analyzer is fluidically connected to the gas collection device for receiving gas from the gas collection device and for analysing the gas to obtain first detection data of the gas; and
a computer for comparing the first detection data with second detection data obtained from a composite detector arranged in the constant-temperature box, so as to obtain a qualitative and quantitative analysis of detection accuracy of the composite detector.