CN216669873U - Cable combustion performance testing device for simulating cable channel environment - Google Patents

Abstract

The utility model provides a cable combustion performance testing device for simulating a cable channel environment, which comprises a shell, wherein a cable bridge for fixing a cable, an ignition unit acting on the cable bridge and an environment control unit for changing the internal environment of the shell are respectively arranged in the shell; the upper layer of the inside of the shell is provided with an optical smoke density measuring unit and a smoke outlet, and the environment control unit can monitor and adjust the temperature, humidity and gas components inside the shell. The utility model has the advantages that: can fix the cable on the cable testing bridge, through the inside environment of environmental control unit adjustment casing, can simulate the tunnel condition, the adaptability is stronger, need not light the cable for different testing arrangement of tunnel preparation through the ignition unit, acquires the burning data of cable based on the smoke density measuring unit, tests convenient to use to cable burning performance.

Description

Cable combustion performance testing device for simulating cable channel environment

Technical Field

The utility model relates to the technical field of cable test equipment, in particular to a cable combustion performance test device for simulating a cable channel environment.

Background

Along with the process deepening of urbanization, the occupation ground space that exists through the mode of overhead line transmission electric power in the past, it is not pleasing to the eye, be unfavorable for shortcomings such as maintenance to have exposed gradually, the substitute is through underground cable channel transmission electric power, however cable channel is located the underground, and for the enclosure space, not only the intensity of a fire can stretch along cable channel when the conflagration takes place and still be unfavorable for the fire fighter to put out a fire and rescue, therefore cable channel's wide application has also brought certain conflagration risk. Combustible materials in the cable channel are mainly cables, and in order to research fire risks brought by the cable channel, the cables in the cable channel are necessary to be subjected to combustion testing.

In the prior art, there is an experimental apparatus which has simulated the physical structure and cable arrangement of a cable tunnel, and the utility model patent application with the publication number of CN103439359A discloses a high-voltage power cable tunnel fire-fighting experimental apparatus and a use method thereof. However, due to the fact that the areas, the altitudes and the ventilation conditions of different cable channels are different, the temperature, the humidity and the pressure conditions in the cable channels are different (for example, some cable channels are located in a high-altitude area, and the oxygen content, the temperature and the pressure are lower than those in a common environment), and part of the cable channels are located in an underground comprehensive pipe gallery, a small amount of other gases (such as natural gas, HCL and the like) exist, the prior art cannot simulate the influence of temperature, humidity, pressure and different gas component conditions on the combustion performance (ignition characteristic, temperature change, fire spreading rate and smoke generation capacity) of the cable in the cable tunnel. And because the cable channel structure size is great, the higher reason of cost, can not be to every cable channel set up test platform, restricted the research to the cable combustion performance in the cable channel. Therefore, an integrated experimental device for simulating the cable channel environment needs to be established, a cable channel cable combustion experiment is developed, and the device has important scientific significance for guiding the cable channel fire and preventing and treating the fire.

In addition, the environmental temperature and humidity detection and control mode adopted in the existing experimental device is not high in efficiency. The cable channel belongs to a large space place, the temperature and humidity detected by an environment temperature and humidity detector cannot represent the temperature and humidity in the whole space, and certain errors exist; similarly, due to the gradient of temperature and humidity propagation, the temperature and humidity field distribution in the large-space equipment is unbalanced, so that the efficiency of controlling the environmental temperature and humidity in the equipment is not high.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a cable combustion performance testing device capable of adjusting simulation conditions according to the environment of a cable channel.

The utility model solves the technical problems through the following technical scheme: a cable combustion performance testing device for simulating a cable channel environment comprises a shell, wherein a cable bridge for fixing a cable, an ignition unit acting on the cable bridge and an environment control unit for changing the internal environment of the shell are respectively arranged in the shell; an optical smoke density measuring unit and a smoke outlet are arranged on the upper layer in the shell, and the environment control unit can monitor and adjust the temperature, humidity, pressure and gas components in the shell; and an armored thermocouple is arranged on the cable bridge.

Preferably, the casing uses fire prevention transparent material, steel sheet and PLASTIC LAMINATED preparation to form the actual structure that can simulate the cable channel, the casing is the cuboid structure, is fixed with a plurality of cable testing bridges on two inside relative sides of casing respectively, the cable testing bridge includes the dead lever of its stationary plane of perpendicular to, is fixed with the cable on the dead lever. And the cables are bound and fixed on the fixed rod.

Preferably, the ignition unit sets up on moving movable support, moving movable support including be fixed in the slide bar of casing bottom and with slide bar sliding fit's vertical support pole, the ignition unit sets up on the bracing piece, the both ends of slide bar are fixed in the both sides of casing, can follow the direction of perpendicular self length and move in the casing bottom, the ignition unit can follow the length direction change position of bracing piece.

Preferably, the ignition unit is communicated with the combustible gas through a pipeline, and a valve for controlling the air inflow is arranged on the pipeline.

Preferably, the environment control unit comprises a humidity control system, a temperature control system and a gas component and pressure control system which are respectively arranged at two sides of the shell;

the fixing surfaces of the humidity control system, the temperature control system and the gas component and pressure control system are adjacent to the fixing surface of the cable bridge;

the humidity control system comprises a humidity detector host, a humidity detector, a humidifier, an adsorption dehumidifier, a first compressor and a humidity conducting pipe;

preferably, the humidity detector adopts a multi-point arrangement of linear voltage humidity sensors;

preferably, the pipe wall of each humidity conducting pipe is provided with first holes with different sizes, and the aperture of one end, close to the first compressor, of each first hole is smaller than that of one end, far away from the first compressor, of each first hole.

The temperature control system comprises a temperature detector host, a temperature detector, a second compressor and a temperature conduction pipe;

preferably, the temperature detector adopts a plurality of linear optical fiber temperature-sensing fire detectors;

preferably, a second hole with different size is formed in the pipe wall of each temperature conduction pipe, and the aperture of one end, close to the second compressor, of each second hole is smaller than that of one end, far away from the second compressor, of each second hole.

Preferably, the method for determining the size of the orifice of the first hole is as follows:

1) calculating the pressure P at the ith orifice_i，

Wherein, P is the standard pressure of the first compressor, mu is the on-way loss coefficient of the humidity conduction pipe, L is the length of the humidity conduction pipe, and n is the total number of the holes of the humidity conduction pipe;

2) calculating the flow q at the ith orifice_i，

Wherein α is a gas state coefficient, c_gIs the orifice flow coefficient, d_iIs the diameter of the ith orifice, k is the isentropic index, P₀Is at standard atmospheric pressure;

3) for all the first holes, the flow rate is equal, i.e.

q₁＝q₂＝…＝q_i

4) The diameter of one of the first holes is determined and the diameters of the other first holes are calculated based on the known diameter of the first hole.

Preferably, the gas composition and pressure control system comprises a plurality of gas cylinders storing different gases, a pressure detector, a vacuum pump and a booster pump. The gas cylinders of the gas component and pressure control system at least comprise gas cylinders in which nitrogen, oxygen, carbon dioxide and carbon monoxide are stored. The vacuum pump and booster pump may reduce or increase the pressure within the housing.

The optical smoke density measuring unit comprises a light source generator and a light source receiver which are respectively arranged on two opposite side surfaces, and the smoke density is calculated according to the intensity of a light signal received by the light source receiver and the intensity of a light signal sent by the light source generator.

The smoke exhaust port is arranged in the middle of the upper surface of the shell, and a fan is further arranged on a smoke exhaust pipe of the smoke exhaust port.

The utility model also provides a use method of the cable combustion performance testing device, which comprises the following steps:

s1: fixing the cable to be tested on the cable bridge according to the cable arrangement mode in the simulation cable channel;

s2: adjusting the ignition unit to a predetermined ignition position;

s3: the environment control unit is used for filling gas with preset components into the shell, meanwhile, the smoke outlet is opened to discharge the original gas in the shell, and then the smoke outlet is closed;

s4: the pressure in the shell is adjusted through the environment control unit, and when the pressure meets the environment requirement, the pressure in the shell is stopped to be adjusted, and the pressure in the shell is continuously monitored.

S5: adjusting the humidity in the shell through the environment control unit, adjusting the temperature in the shell to a preset value through the environment control unit, stopping adjusting the temperature and humidity in the shell after the humidity and the temperature meet the environment requirements, and continuously monitoring the temperature and the humidity in the shell;

s6: opening the optical smoke density measurement unit;

s7: adjusting the size of a fire source of an ignition unit, heating and igniting the cable to be tested, collecting environmental temperature and humidity data monitored by an optical smoke density measuring unit, an armored thermocouple on a cable bridge and an environmental control unit until the cable is completely extinguished, and stopping data collection;

s8: and opening the smoke outlet, discharging the smoke in the shell, and cleaning the shell.

The cable combustion performance testing device for simulating the cable channel environment provided by the utility model has the advantages that:

1. in the aspect of the size of the experimental device, the experimental device is designed according to the full size, compared with other non-full-size experimental devices, the experimental device is closer to the real situation in a cable channel, the error caused by the volume effect is reduced, the change situations of smoke, temperature, humidity, pressure and gas components during the combustion of the cable in the channel can be more truly researched, and the reliability of the experimental result is higher.

2. In the aspect of ventilation conditions of the experimental device, because the cable channels used at present are provided with fire walls or fire doors as fire partitions, the cable channels in one interval are approximate to a closed space, and the shell is the closed space after the ventilation opening is closed, so that the ventilation conditions of the cable channels of two fire partitions can be simulated, and the experiment is closer to the actual situation.

3. In the aspect of the cable placement and ignition positions of the experimental device, cables on a cable bridge in the device can be placed according to the cable placement modes in a cable channel, so that the condition that a single cable fires to radiate adjacent cables is simulated, and the influence of different placement modes and different cable intervals on the fire development condition in the cable channel is researched. The ignition unit can change ignition position and flame size in the space in the casing, and the influence of different positions of getting on a fire and source of a fire size to cable channel fire development condition is simulated.

4. In the aspect of cable channel environment simulation, the initial environmental conditions (temperature, humidity, pressure and gas components) in the cable channel can be changed through the environment control unit, so that the conditions in the cable channel in different regions, different altitudes and different maintenance states are simulated, and the influence of environmental factors on the cable combustion performance, fire development and smoke change in the cable channel is researched. The method provides certain scientific basis for fire prevention and extinguishing design, relevant standard requirements and fire extinguishing rescue strategies of cable channels in different areas.

5. In the aspect of monitoring contents of cable combustion conditions of the cable channel, the environment temperature and humidity change, the pressure change, the gas component change, the smoke density change and the temperature change of the cable on the cable bridge in the shell are monitored through the environment control unit, the optical smoke density measuring unit, the armored thermocouple and the like during cable combustion, so that the combustion performance change of the cable in the cable channel under different environments and the rule of influence of the cable on the environment of the cable channel after the cable is ignited are researched.

6. In the aspect of a cable channel environment temperature and humidity monitoring mode, the utility model adopts a mode of arranging a plurality of linear optical fiber temperature-sensing fire detectors to detect the environment temperature of the cable channel, adopts a linear voltage humidity sensor to arrange a plurality of points to detect the environment humidity of the cable channel, and simultaneously detects the environment temperature and humidity of different positions in a large space, thereby reducing errors.

7. In the aspect of the environmental temperature and humidity control mode of the cable channel, the temperature and humidity of the environment are changed in a multi-pipeline conduction mode. Because the pipeline wall of the conduction pipe is provided with outlets (holes) with different sizes, the outlet of the near input end is small and the outlet of the far input end is large by utilizing the fluid mechanics principle, the purpose of regulating and controlling the temperature and the humidity of a large space is achieved, and the temperature and humidity control efficiency is improved and promoted.

Therefore, when the physical structure in the simulation cable channel is used for carrying out a cable combustion experiment, the simulation experiment device can also be used for simultaneously simulating the actual environment of the cable channel, so that the experiment of exploring the influence of different environmental conditions on the cable combustion performance in the cable channel and the channel environment is realized, the adaptability is strong, and different testing devices do not need to be manufactured for different tunnel conditions. The utility model can provide a reasonable fire condition simulation experiment for the cable channel, comprehensively explores the influence of different environmental temperatures, environmental humidity, pressures and gas components on the combustion performance of the cable in the cable channel, thereby providing scientific reference significance for the fire development, the smoke rule, the combustion characteristic and the fire extinguishing and rescue strategy of the cable in the cable channel under different regions and different environmental conditions; the result can be used for researching the ignition characteristic and the combustion performance of the cable in the cable channel under the influence of various conditions such as different regions, different altitudes, different maintenance conditions and the like, and has a certain guiding function for the design of a cable channel fire prevention and extinguishing system in the future, the prediction of the fire development condition of the cable channel in different environments and the establishment of related specifications. Through humidity control system and temperature control system, the humiture change in collection and the control environment that can be accurate improves control efficiency, improves the degree of accuracy of experiment.

Drawings

Fig. 1 is a schematic side view of a cable combustion performance testing apparatus for simulating a cable channel environment according to an embodiment of the present invention;

fig. 2 is a schematic front view of a cable combustion performance testing apparatus for simulating a cable channel environment according to an embodiment of the present invention;

FIG. 3 is a schematic side view of a part of the circuit piping layout of the cable combustion performance testing apparatus for simulating a cable channel environment according to an embodiment of the present invention;

fig. 4 is a schematic front view of a part of the wiring duct layout of the cable combustion performance testing apparatus for simulating a cable channel environment according to an embodiment of the present invention.

Detailed Description

In order that the objects, technical solutions and advantages of the present invention will become more apparent, the present invention will be further described in detail with reference to the accompanying drawings in conjunction with the following specific embodiments.

With reference to fig. 1 and fig. 2, the present embodiment provides a cable combustion performance testing apparatus for simulating a cable channel environment, which includes a housing 1, a cable tray 2 for fixing a cable (not shown), an ignition unit 3 acting on the cable tray, and an environment control unit (not shown) for adjusting an environment inside the housing 1 are respectively disposed inside the housing 1, and an armored thermocouple (not shown) is disposed on the cable tray 2, so that a temperature of a surface of the cable fixed on the cable tray 2 can be directly obtained; the upper strata of casing 1 inside still is provided with optics smoke density measuring unit 5 and exhaust port 6 respectively, the environmental control unit can monitor and adjust 1 inside humiture, pressure and the gaseous component of casing to can simulate cable channel's environment as required, the adaptability is stronger, improves the authenticity of experimental result.

The testing arrangement that this embodiment provided can fix the cable on cable testing bridge 2, through the environment of environment control unit adjustment casing 1 inside, can simulate most tunnel condition, and adaptability is stronger, need not light the cable for the different testing arrangement of different tunnel preparation, through ignition unit 3, acquires the combustion data of cable based on smoke density measuring unit 5 and armor thermocouple, tests convenient to use to cable combustion performance.

The casing 1 is of a cuboid structure, and a person skilled in the art can also change the structure of the casing 1 according to the adaptability of the tunnel structure, wherein a plurality of cable bridges 2 are respectively fixed on two opposite side surfaces inside the casing 1, each cable bridge 2 comprises a fixed rod (not shown) perpendicular to the fixed surface, and the cables are fixed on the fixed rods; during the test, the fixed position of the cable and the relative position relation of the plurality of cables can be determined according to the actual environment; the armored thermocouple can not be ignited by flame of the cable, the temperature information of the cable can be acquired, and the armored thermocouple is opened to continuously acquire the parameters before the test is started.

The cable needs to be fixed along the length direction of the cable bridge 2, the shell 1 is provided with a movable door (not shown) which can be opened and can operate the interior of the shell, the cable is flexible and can be directly bound on the cable bridge 2 by using materials such as iron wires, and the like.

As the housing 1 has a plurality of cable trays 2 inside, the ignition unit 3 is also arranged to be able to change position in a three-dimensional space inside the housing 1, in particular, the ignition unit 3 is arranged on a moving bracket (not shown); referring to fig. 1, the movable bracket includes a sliding rod 71 fixed at the bottom of the housing 1 and a vertical support rod 72 slidably engaged with the sliding rod 71, the ignition unit 3 is disposed on the support rod 72, two ends of the sliding rod 71 are fixed at two sides of the housing 1, the sliding rod 71 can move at the bottom of the housing 1 along a direction perpendicular to the length of the sliding rod 71, and the ignition unit 3 can change its position along the length of the support rod 72, thereby realizing the position adjustment of the ignition unit 3 in the whole space.

Since the position to be ignited is known before ignition, the position of the ignition unit 3 can be manually adjusted under the condition of opening the housing 1, polished rods (not shown) which are slidably matched with the ends of the sliding rods 71 can be respectively arranged at the two ends of the sliding rods 71, after the supporting rods 72 are slidably matched with the sliding rods 71, the ignition unit 3 is slidably matched with the supporting rods 72, the sliding parts can be fastened by using bolts and the like, when the position needs to be adjusted, the ignition unit 3 is moved to the position below the cable bridge 2 for fixing the cable by loosening screws, and then the position is locked by the bolts.

A person skilled in the art can also adjust the position of the ignition unit 3 in an automatic control manner, the sliding rod 71, the support rod 72 and the ignition unit 3 can be driven by a linear driving structure such as an air cylinder, specifically, two polished rods (not shown) perpendicular to the sliding rod 71 are respectively arranged on two sides of the sliding rod 71, the air cylinder is fixed on at least one polished rod, the power end of the air cylinder is fixedly connected with the sliding rod 71, the sliding rod 71 is driven to move linearly by the extension and contraction of the air cylinder, and according to the same principle, the air cylinder for driving the support rod 72 to move linearly is fixed on the sliding rod 71, and the air cylinder for driving the ignition unit 3 to move linearly is fixed on the support rod 72; at this time, attention needs to be paid to the fact that a telescopic fireproof pipe, such as a metal corrugated pipe, is used for a gas supply pipeline of the cylinder; so that the cylinder is not restricted from moving along with the fixed part and is not ignited by the flame of the cable.

Furthermore, polished rods which are in sliding fit with the sliding rods 71 can be respectively arranged at two ends of the sliding rods 71, then an air source is connected to the end parts of at least one polished rod, magnets are placed in the polished rods, the sliding rods 71 can change positions along with the magnets, the positions of the magnets are adjusted by changing the pressure of the air source, and then the positions of the sliding rods 71 are changed to adjust the positions of the ignition units 3; the support rod 72 and the ignition unit 3 are driven to move in the same manner.

Ignition unit 3 has combustible gas through pipeline 31 intercommunication, and is same, and fire-retardant scalable pipe should also be chooseed for use to its pipeline 31, is provided with the valve (not shown) of control air input on the pipeline 31 to control flame size that can be convenient, the mode that 3 tip of ignition unit struck sparks through the electron can, concrete technique is mature prior art, and this application is no longer repeated.

With reference to fig. 2, the environmental control unit comprises a humidity control system 41, a temperature control system 42 and a gas and pressure control system 43, which are respectively disposed on both sides of the housing 1, and the humidity control system 41, the temperature control system 42 and the gas and pressure control system 43 are disposed on a side surface adjacent to the fixing surface of the cable tray 2.

Referring to fig. 4 in conjunction with fig. 3, the humidity control system 41 includes a humidity detector host (not shown), a humidity detector 411, a humidifier (not shown), an adsorption dehumidifier (not shown), a first compressor (not shown), and a humidity conducting pipe 412; the temperature control system 42 comprises a temperature detector host (not shown), a temperature detector 421, a second compressor (not shown) and a temperature conduction pipe 422; the gas component and pressure control system 43 includes a pressure detector, a vacuum pump, a booster pump, and a plurality of gas cylinders in which different gases are stored, including at least gas cylinders in which nitrogen, oxygen, carbon dioxide, and carbon monoxide are stored, respectively. The humidity detector 411 is a linear voltage output type integrated humidity sensor, the temperature detector 421 is a linear optical fiber temperature-sensing fire detector, each temperature conduction tube determines the fixed position of the detector in the shell 1 according to the experimental requirements, and is electrically connected with the humidity detector host and the temperature detector host which are positioned outside the shell 1 through wires respectively, heat-resistant tubes or other modes are used for protection during wiring, first holes with different sizes are arranged on the tube wall of the humidity conduction tube 412, the hole diameter at one end close to the first compressor is smaller, and the hole diameter at one end far away from the first compressor is larger; the pipe wall of each temperature conduction pipe 422 is also provided with second holes with different sizes, the hole area at the end close to the second compressor is smaller, and the hole area at the end far away from the second compressor is larger, so that the uniform regulation and control of the temperature and the humidity at different positions are realized by virtue of the sizes of the first hole and the second hole, and the control precision is improved; the size and distribution of the apertures on the pipe wall are determined according to the transmission power and the type selection of the conduction pipe.

Specifically, the method for determining the size of the orifice of the first hole is as follows:

1) calculating the pressure P at the ith orifice_i，

Wherein, P is the standard pressure of the first compressor, mu is the on-way loss coefficient of the humidity conduction pipe, L is the length of the humidity conduction pipe, and n is the total number of the holes of the humidity conduction pipe;

2) calculating the flow q at the ith orifice_i，

Wherein α is a gas state coefficient, c_gIs the orifice flow coefficient, d_iIs the diameter of the ith orifice, k is the isentropic index, P₀Is at standard atmospheric pressure;

at the time of specific calculation, the gas state coefficient

Wherein M is the molar mass of air, R is a gas constant, and T is the air temperature; orifice flow coefficient c_gThe values of (a) are related to the shape of the orifice: circular orifice c_g1.0; rectangular orifice c_g0.9; triangular orifice c_g0.95; the magnitude of the isentropic index k is 1.4.

3) For all the first holes, the flow rate is equal, i.e.

q₁＝q₂＝…＝q_i

4) The diameter of one of the first holes is determined and the diameters of the other first holes are calculated based on the known diameter of the first hole.

The diameter of the second hole is determined by the same method as the first hole, and parameters corresponding to the first compressor and the humidity conduction pipe are replaced by parameters of the second compressor and the temperature conduction pipe.

The optical smoke density measuring unit comprises a light source generator 51 and a light source receiver 52 which are respectively arranged on two opposite side surfaces, and the smoke density can be calculated according to the numerical values of the light signals received by the light source receiver 52 and the light signals sent by the light source generator 51. The exhaust port 6 is arranged in the middle of the upper surface of the shell 1, the exhaust pipe 61 of the exhaust port 6 is further provided with a fan 62, and the combusted flue gas is rapidly exhausted by the fan 62.

Based on the above structure, those skilled in the art should understand that there is also a need to provide the necessary circuit and control elements for the test device to operate normally, and in the case that the operation mode has been clearly described in the present application, the specific control mode is the conventional technical means.

In this embodiment, the temperature range of the simulated cable channel is-10 ℃ to 80 ℃, the humidity range is 0% to 90%, and the pressure range is 50kPa to 150kPa, and the environment control is performed in the following manner: acquiring a humidity value in the shell 1 through a humidity detector, feeding a result back to a humidity detector host, if the current humidity is lower than the preset environment humidity, controlling the humidifier to work until the preset environment humidity is reached, and if the current humidity is higher than the preset environment humidity, controlling the adsorption dehumidifier to dehumidify until the preset environment humidity is reached; in the same way, when the temperature detected by the temperature detector is too low, the temperature detector host controls the compressor to start to heat, and when the temperature is too high, the temperature detector host controls the compressor to refrigerate; in the same way, when the pressure detector detects that the pressure is too low, the upper computer controls the booster pump to increase the ambient pressure, an air inlet of the booster pump is connected to an outlet of an air bottle with a set component, and when the pressure is too high, the upper computer controls the vacuum pump to reduce the pressure; according to the composition of the ambient gas, the gas composition and pressure control system 43 controls a plurality of gas cylinders to inflate the shell 1 at corresponding speed ratios, and opens the smoke outlet 6 to discharge the original gas in the shell 1. The optical smoke density measuring unit also transmits data to an upper computer for processing and calculation, and outputs a result. The embodiment also provides a using method of the cable combustion performance testing device, which comprises the following steps:

s1: according to the simulated actual condition of the cable channel, a cable to be tested is fixed on the cable bridge frame 2, and the cable to be tested is bound and fixed through iron wires in the embodiment;

s2: moving the ignition unit to a predetermined ignition position;

s3: the gas component and pressure control system 43 of the environment control unit is used for filling gas with preset components into the shell 1, meanwhile, the smoke outlet 6 is opened to discharge the original gas in the shell 1, the smoke outlet 6 is closed after the gas is discharged, and the process of adjusting the gas lasts for at least three minutes in the embodiment;

s4: the pressure in the housing 1 is regulated by the gas composition and pressure control system 43 of the environmental control unit, and when the pressure meets the environmental requirements, the regulation of the pressure in the housing is stopped, and the pressure in the housing is continuously monitored.

S5: adjusting the humidity in the shell 1 through a humidity control system 41 of the environment control unit, then adjusting the temperature in the shell 1 to a preset value through a temperature control system 42 of the environment control unit, and stopping adjusting the environment after the humidity and the temperature meet the environment requirements, and keeping monitoring the environment temperature and humidity in the shell 1;

s6: opening the optical smoke density measurement unit;

s7: adjusting the size of a fire source of the ignition unit 3, heating and igniting the cable to be tested, collecting temperature and humidity data monitored by the optical smoke density measuring unit, the armored thermocouple and the environment control unit until the cable is completely extinguished, and stopping data acquisition;

s8: and opening the smoke outlet 6, discharging the smoke in the shell 1, and cleaning the shell 1.

If other tests are needed, the process is repeated.

Due to different areas, different altitudes and different aging degrees, the environmental characteristic difference of the cable channel is large. For example, in a cable channel in the Hainan area of China, the temperature is kept at about 60 ℃ throughout the year, the humidity is often about 80%, and methane seeps from the underground into the cable channel. In such an environment, the ignition characteristics and combustion performance of the cable are greatly different from those of eastern Henan and other areas (the temperature is about 25 ℃, the humidity is about 40%, and the atmospheric pressure is about 95 kPa), northeastern areas (the temperature is about 10 ℃, the humidity is about 15%, and the atmospheric pressure is about 100 kPa), Tibet areas (the temperature is about 15 ℃, the humidity is about 30%, the atmospheric pressure is about 65kPa, and the oxygen content is about 15% of the air) and other areas. Due to the fact that the partial cable channels are long in construction time and improper in maintenance and the like, the drainage system works badly, and the humidity in the cable channels is larger than that of other cable channels. And partial cable channel arranges in the utility tunnel, and the gas that leaks in other pipelines also can exert an influence to the ignition characteristic and the combustion behavior of cable.

The testing device and the using method provided by the embodiment can be used for measuring the ignition characteristic and the combustion performance of the cable under the conditions of different temperatures, humidity, pressure and gas components, and researching the influence of different environmental conditions on the ignition characteristic and the combustion performance of the cable. The result can be used for researching the ignition characteristic and the combustion performance of the cable in the cable channel under the influence of various conditions such as different regions, different altitudes, different maintenance conditions and the like, and has a certain guiding function for the design of a cable channel fire prevention and extinguishing system in the future, the prediction of the fire development condition of the cable channel in different environments and the specification of related specifications.

Claims (5)

1. The utility model provides a cable burning behavior testing arrangement of simulation cable channel environment which characterized in that: the ignition device comprises a shell, wherein a cable bracket for fixing a cable, an ignition unit acting on the cable bracket and an environment control unit for changing the internal environment of the shell are respectively arranged in the shell; an optical smoke density measuring unit and a smoke outlet are arranged on the upper layer in the shell, and the environment control unit can adjust the temperature, the humidity and the gas components in the shell;

the environment control unit comprises a humidity control system, a temperature control system and a gas component and pressure control system which are respectively arranged at two sides of the shell;

the fixing surfaces of the humidity control system, the temperature control system and the gas component and pressure control system are adjacent to the fixing surface of the cable support;

the humidity control system comprises a humidity detector host, a humidity detector, a humidifier, an adsorption dehumidifier, a first compressor and a humidity conducting pipe; the humidity detector adopts a multi-point arrangement of linear voltage humidity sensors; the pipe wall of each humidity conduction pipe is provided with first holes with different sizes, and the aperture of one end close to the first compressor is smaller than that of one end far away from the first compressor;

the temperature control system comprises a temperature detector host, a temperature detector, a second compressor and a temperature conduction pipe; the temperature detector adopts a plurality of linear optical fiber temperature-sensing fire detectors; the pipe wall of each temperature conduction pipe is provided with second holes with different sizes, and the aperture of one end close to the second compressor is smaller than that of one end far away from the second compressor;

the gas composition and pressure control system includes at least a gas cylinder storing nitrogen, oxygen, carbon dioxide and carbon monoxide.

2. The cable combustion performance testing device for simulating the cable channel environment according to claim 1, wherein: the casing is the cuboid structure, is fixed with a plurality of cable support on two inside relative sides of casing respectively, the cable support includes the dead lever of its stationary plane of perpendicular to, is fixed with the cable on the dead lever.

3. The cable combustion performance testing device for simulating the cable channel environment according to claim 2, wherein: and the fixed rod is provided with an armored thermocouple for acquiring the surface temperature of the cable, and the cable is bound and fixed on the fixed rod.

4. The cable combustion performance testing device for simulating the cable channel environment according to claim 2, wherein: the ignition unit is communicated with combustible gas through a pipeline, and a valve for controlling air inflow is arranged on the pipeline.

5. The cable combustion performance testing device for simulating the cable channel environment according to claim 1, wherein: the optical smoke density measuring unit comprises a light source generator and a light source receiver which are respectively arranged on two opposite side surfaces, and the smoke density is calculated according to the intensity of an optical signal received by the light source receiver and the intensity of an optical signal sent by the light source generator;

the smoke exhaust port is arranged in the middle of the upper surface of the shell, and a fan is further arranged on a smoke exhaust pipe of the smoke exhaust port.

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