KR20240000709U - Apparatus for Inspecting Performance Equalization of Flame Detector - Google Patents

Abstract

The present invention relates to a device for smoothly testing the performance of a flame detector that detects and detects flames generated when a fire occurs and generates a fire signal. It has a flat plate shape and has a first rail groove at regular intervals in the horizontal direction on a plane. A first bed (10) on which (11) is formed and a second rail groove (12) is formed on the side in the horizontal direction; A flame detector (90) fixedly coupled to one upper surface of the first bed (10); A first infrared ray emitting device (20) movably or fixedly coupled to the first rail groove (11) of the first bed (10) and emitting infrared rays in a certain wavelength band to the flame detector (90); It has a flat shape, and a third rail groove 61 is formed at regular intervals in the horizontal direction on the plane, and a fourth rail groove 62 is formed in the horizontal direction on the side, and at the side of the first bed 10. a second bed (60) coupled to the first bed (10) at a certain angle; a second infrared radiation device 30 that is movably or fixedly coupled to the second rail groove 12 of the second bed 60 and radiates infrared rays in a certain wavelength band to the flame detector 90; The second hinge protrusion 72 coupled to the front of the second bed 60 to the first hinge protrusion 71 protruding from the second rail groove 12 of the first bed 10 is connected to the first hinge axis. A first angle adjustment bracket (70) hinged at (73); The fourth hinge protrusion 77 coupled to the side of the second bed 60 and the third hinge protrusion 76 protruding from the second rail groove 12 of the first bed 10 are connected to the first hinge shaft. A second angle adjustment bracket (75) hinged at (73); It includes a controller 100 that is fixedly installed on the upper surface of the first bed 10 and selects the operation, radiation dose control, transmittance measurement, and radiation dose measurement of the first infrared ray emitter 20 or the second infrared ray emitter 30. This was accomplished. This design uses a digital infrared radiation sensor to always radiate a constant wavelength, making it extremely easy to find and correct the error range of the flame detector, and meets the technical standards for flame detectors presented by the Korea Fire Industry & Technology Institute, a national fire protection certification agency. Fire source data from actual fire tests can be collected through various weather conditions, such as actual fire data, non-fire data, and environmental data, using actual flame detectors, using a verification method in accordance with the rules and regulations, and the collected data can be graphed and compared. The average value can be obtained through analysis, and based on the obtained average value, it is adjusted through the controller of the inspection device so that the same data as the average value of the flame detector is emitted, allowing inspection of the front, left, right, non-fire, etc. .

Description

Flame detector performance equalization inspection device {Apparatus for Inspecting Performance Equalization of Flame Detector}

The present invention relates to a device for smoothing the performance of a flame detector, and more specifically, to a device for smoothing and testing the performance of a flame detector that senses and detects flames generated when a fire occurs and generates a fire signal.

Generally, when a fire occurs, a flame detector generates smoke, heat, and flames. At this time, it analyzes optical characteristics such as ultraviolet (UV) wavelength, infrared (IR) wavelength, and flickering generated from the flame in a complex manner. It is a device that detects fire. Flame detectors can respond faster and more accurately than smoke or heat detectors due to the mechanism they use to detect flames. Therefore, it is mainly installed in places that cannot be detected by existing smoke detectors or heat detectors.

In addition, a flame detector is a fire detector designed to detect a specific wavelength when a fire occurs using an infrared sensor and an ultraviolet sensor, and generate a fire signal by processing and analyzing the data from the detected sensor. Flame detectors are broadly divided into the following three types.

First, it is an ultraviolet flame detector that uses only an ultraviolet (UV) sensor. Unlike other sensors, the ultraviolet sensor has the advantage of very fast detection performance, but it can malfunction in devices and environments that emit ultraviolet rays such as sunlight, halogen, and metal. It has many disadvantages, so it is better to install it in dark places such as inside ducts rather than outdoors or outside.

Second, it is a UV/IR flame detector that uses a combination of an ultraviolet (UV) sensor and an infrared (IR) sensor. In order to reduce malfunctions of the UV flame detector, an infrared (IR) sensor is added and filtered to significantly reduce malfunctions. In environments where a lot of evaporative gas is generated, ultraviolet rays cannot penetrate the evaporative gas, making detection difficult, so the sites where it can be installed are limited.

Third, the IR3 flame detector uses three infrared (IR) sensors. In order to compensate for the shortcomings of the above two types of flame detectors, it uses three infrared sensors to make up for many of the shortcomings. The three infrared sensors detect different wavelength bands, and each flame detector manufacturer selects and manufactures different wavelength bands. This is because infrared rays of various wavelength bands are emitted from the fire source when a fire occurs. Among them, they do not occur often in general environments, but they occur frequently only in fire sources and the wavelength band transmitted over long distances is approximately 4 to 4.9㎛, and an infrared sensor that detects this wavelength band is selectively used to detect fire occurrence. In other words, in order to block disturbances such as sunlight or halogen, which includes a wavelength band of approximately 4 to 4.9㎛, as well as people and animals in the short distance, each flame detector manufacturer selectively applies a wavelength sensor to create an IR3 flame detector. manufactures.

When manufacturing a flame detector, the window glass installed on the flame detector is important for improving performance and stabilization. In other words, the window glass of the flame detector is not only for the purpose of checking the status and internal protection, but also detects the wavelength of the specific wavelength of infrared and ultraviolet rays generated when a fire occurs, passes through the window glass of the flame detector and reaches the sensor. . Therefore, the transmittance of a window is very important, but the degree of transmittance of a window cannot be determined by its appearance, so a device that can measure the transmittance is needed.

Additionally, there is a problem with the performance verification method of the flame detector. In other words, as a fire detector, the priority of a flame detector is to detect fire very quickly and accurately. However, some manufacturers simply verify detection by using a small candle or lighter to adjust the sensitivity setting of the flame detector and sell products that have passed the test. And in the case of some larger manufacturers, they set up test sites similar to the performance verification method implemented by the Korea Fire Industry & Technology Institute, conduct tests, find products that are operating normally, and undergo inspection. However, there are clearly errors between the parts used in flame detectors, and these errors are simply perceived as normal and are manufactured, inspected, and sold. Products manufactured in this way may malfunction due to various environmental factors at the actual installation site. At this time, it is not possible to determine exactly what problem is causing the malfunction of the installed product, and attempts are being made to solve the problem by simply replacing the malfunctioning flame detector, which leads to serious problems that can result in life and property damage in the event of an actual fire in addition to continuous problems. there is.

Republic of Korea Patent Publication No. 10-1742122 (announced on May 31, 2017) Republic of Korea Patent Publication No. 10-2080070 (announced on February 24, 2020) Republic of Korea Patent Publication No. 10-2088143 (announced on March 11, 2020)

The purpose of this invention is to solve the above problems and improve performance and stability when manufacturing flame detectors.

In addition, another purpose of this design is to find and correct the error range of the flame detector by using a digital radiation sensor to emit a certain wavelength.

In addition, this design takes the actual fire data, non-fire data, environmental data, and data collected according to the weather-specific verification method in accordance with the technical standards and regulations of the flame detector as an average value, and radiates this average value from the inspection device to detect the flame. Another purpose is to inspect the detector.

In addition, another purpose of the present invention is to manufacture a flame detector with the same performance from the data set by the inspection device for more stable and accurate fire detection.

In order to achieve the above object, the present invention includes: a first bed that is flat and has first rail grooves formed at regular intervals in the horizontal direction on a plane, and second rail grooves formed in the horizontal direction on the side; A flame detector fixedly coupled to one upper surface of the first bed; a first infrared ray emitting device that is movably or fixedly coupled to the first rail groove of the first bed and radiates infrared rays in a certain wavelength band to the flame detector; It has a flat shape, and a third rail groove is formed at regular intervals in the horizontal direction on the plane, a fourth rail groove is formed in the horizontal direction on the side, and is coupled to the first bed at a certain angle on the side of the first bed. 2nd bed; a second infrared radiation device movably or fixedly coupled to the second rail groove of the second bed and emitting infrared rays in a certain wavelength band to the flame detector; A first angle adjustment bracket in which a second hinge protrusion coupled to the front of the second bed is hinged to a first hinge protrusion protruding from the second rail groove of the first bed and coupled to the first hinge axis; A second angle adjustment bracket in which a fourth hinge protrusion coupled to the side of the second bed is hinged to the first hinge axis to a third hinge protrusion protrudingly coupled to the second rail groove of the first bed; A flame detector performance smoothing inspection device is provided, which is fixedly installed on the upper surface of the first bed and includes a controller that selects the operation, radiation dose control, transmittance measurement, and radiation dose measurement of the first infrared radiation device or the second infrared radiation device. It is a characteristic.

Additionally, in the present invention, a first ruler may be coupled to the surface of the first bed in the horizontal direction, and a second ruler may be coupled to the surface of the second bed in the horizontal direction.

In addition, in the present invention, the first hinge protrusion is coupled to the second rail groove of the first bed so as to be movable or fixed, the second hinge protrusion is fixedly coupled to the front of the second bed, and the third hinge protrusion is It is coupled to be movable or fixed to the second rail groove of the first bed, and the fourth hinge protrusion can be coupled to be movable or fixed to the side of the second bed.

In addition, in the present invention, the first infrared radiating device and the second infrared radiating device are installed on a flat plate with a pair of vertical bars facing each other at a certain distance from the left and right, and a horizontal horizontal bar is integrated at the top of the vertical pole. An installed housing, a lifting hole is formed at the center, a pair of guide holes are formed at a certain interval from the lifting hole, a lifting table that goes up and down inside the housing, and a screw fastening to the lifting hole, the upper end of which is the center of the horizontal bar. A lifting bolt that protrudes through and is fixedly installed at the lower end at the center of the surface of the plate, a knob that is fixedly coupled to the upper end of the lifting bolt that protrudes upward through the horizontal bar, and a certain distance to the left and right from the lifting bolt. It is installed with an upper end fixed to the lower surface of the horizontal bar, a lower end fixed to the surface of the plate, a pair of lifting rails installed through the guide hole to support the lifting and lowering of the lifting table, and Each may include an infrared radiation sensor module fixedly coupled to the front of the elevator platform.

Additionally, in the present invention, a third ruler may be coupled to the inner surface of the vertical bar in the vertical direction.

In addition, in the present invention, according to claim 4, the first infrared ray emitting device has a fixing piece inserted into the first rail groove, and is coupled through a fixing hole formed in the plate and a coupling hole formed in the fixing piece, and the coupling hole of the fixing piece The plate is closely coupled to the surface of the first bed by screwing the fixing bolt and the fixing piece, including the fixing bolt, and the second infrared radiating device has a fixing piece inserted into the third rail groove and is formed on the plate. The plate can be closely coupled to the surface of the first bed by screwing the fixing bolts and the fixing piece, including a fixing bolt that is penetrated through the coupling hole formed in the fixing hole and the fixing piece, and screwed into the coupling hole of the fixing piece.

In addition, in the present invention, the infrared radiation sensor module is fixedly installed in a glass light emitting jig with a window glass room installed, and a multi-layer hot plate that generates and radiates multiple infrared wavelength bands by heating at a certain temperature is installed inside, and the window An infrared wafer bandpass filter may be incorporated into the glass room surface.

Additionally, in the present invention, the infrared wafer band filter can filter the 1-15㎛ wavelength band generated from the multi-layer hot plate into the 4.3-4.55㎛ wavelength band.

In addition, in the present invention, the controller includes a main power switch that connects or cuts off the applied power, a selection switch that selects the first infrared radiation device or the second infrared radiation device, and a radiation switch that measures the transmittance of the window glass. and a selection switch for selecting whether to operate the first infrared radiation device, a selection switch for selecting whether to operate the second infrared radiation device, and a knob for variably controlling the radiation amounts of the first infrared radiation device and the second infrared radiation device. It may include a knob for variably controlling the radiation amount of the first infrared radiation device, a knob for variably controlling the radiation amount of the second infrared radiation device, and a knob for variably controlling the radiation amount for measuring the transmittance of the window glass.

Additionally, in the present invention, a single or multiple infrared sensors may be installed in the flame detector, or an infrared sensor and an ultraviolet sensor may be installed.

According to this design, it is extremely easy to find and correct the error range of the flame detector by always emitting a certain wavelength using a digital infrared radiation sensor, and it is very easy to find and correct the error range of the flame detector presented by the Korea Fire Industry & Technology Institute, a national fire protection certification agency. Fire source data from actual fire tests can be collected using actual flame detectors through various weather conditions such as actual fire data, non-fire data, and environmental data, using a verification method in accordance with technical standards and regulations, and the collected data can be graphed. The average value can be obtained through comparative analysis, and the front, left, right, non-fire, etc. can be inspected by adjusting it through the controller of the inspection device so that the same data as the average value of the flame detector is emitted based on the obtained average value. , the reliability of verification can be increased by using a detector whose average value has been verified, and by adjusting the software and hardware parts according to the status after verification, it can be set to obtain constant data at all times, and the performance of the set flame detector is the same. It has the advantage of enabling more stable and accurate fire detection, minimizing damage to life and property.

Figure 1 is a perspective view showing a flame detector performance smoothing inspection device as an example of the present invention.
Figure 2 is a perspective view showing the infrared radiation device of the flame detector performance smoothing inspection device according to the present invention.
Figure 3 is a plan view showing the combination and angle adjustment of the first bed and the second bed in the infrared radiation device of the flame detector performance smoothing inspection device according to the present invention.
Figure 4 is a cross-sectional view showing the fixing structure of the bed and the infrared radiation device in the flame detector performance smoothing inspection device according to the present invention.
Figure 5 is a schematic diagram showing the infrared radiation sensor module in the flame detector performance smoothing inspection device according to the present invention.
Figure 6 is a perspective view illustrating the controller of the flame detector performance smoothing inspection device according to the present invention.
Figure 7 is a schematic diagram showing the installation structure of the infrared sensor installed in the flame detector in the flame detector performance smoothing inspection device according to the present invention.
Figures 8 and 9 are schematic diagrams showing a device for measuring the transmittance of the window glass of a flame detector in the present invention.
Figure 10 is a graph measuring the transmittance according to the presence or absence of window glass of the flame detector in the present invention.
Figures 11 and 12 are schematic diagrams showing the test method of the flame detector of the Korea Fire Industry & Technology Institute in the present design.
Figure 13 is a schematic diagram illustrating the operation test of the flame detector performance smoothing inspection device according to the present invention.

Hereinafter, an embodiment of the flame detector performance smoothing inspection device according to the present invention will be described in detail with reference to the attached drawings.

In FIG. 1, the first bed 10 has a substantially flat plate shape, and first rail grooves 11 are formed at regular intervals in the horizontal direction on the plane. A second rail groove 12 is formed on the side of the first bed 10 in the horizontal direction.

The flame detector 90 is fixedly installed on the surface of the first bed 10. And the first infrared radiation device 20 is installed in the front at a certain distance from the flame detector 90. The first infrared radiation device 20 is movably or fixedly coupled to the first rail groove 11 of the first bed 10, and the first infrared radiation device 20 is a flame detector 90 and is fixed to the first rail groove 11 of the first bed 10. It radiates infrared rays in the wavelength range.

The second bed 60 has a substantially flat plate shape, and third rail grooves 61 are formed at regular intervals in the horizontal direction on the plane. The second bed 60 has a fourth rail groove 62 formed horizontally on its side. And the second bed 60 is coupled to the first bed 10 at a certain angle on the side of the first bed 10.

The second infrared radiation device 30 is movably or fixedly coupled to the second rail groove 12 of the second bed 60. And the second infrared radiation device 30 radiates infrared rays in a certain wavelength band to the flame detector 90.

The first infrared radiation device 20 coupled to the first bed 10 and the second infrared radiation device 30 coupled to the second bed 60 have the same configuration and structure, and in FIG. 2, the housing ( 21, 31, a pair of vertical bars (23, 33) are installed facing each other at a certain distance on the left and right on the plate-shaped plates (22, 32), and a horizontal bar (horizontal bar) is installed horizontally at the top of the vertical bars (23, 33). 24, 34) are installed integrally. A space is formed inside the vertical bars 23 and 33 and the horizontal bars 24 and 34. In addition, the lifting platforms (40, 50) installed horizontally in the space have lifting holes (41, 51) formed at the centers, and a pair of guide holes (42, 52) at a certain distance from the lifting holes (41, 51). is formed and is raised and lowered inside the housings 21 and 31. The elevating bolts (25, 35) are screwed to the elevating holes (41, 51), and the elevating boards (40, 50) rise or fall according to the forward or reverse rotation of the elevating bolts (25, 35). In addition, the upper ends of the lifting bolts 25 and 35 protrude through the centers of the horizontal bars 24 and 34, and the lower ends are fixed to the center of the surfaces of the plates 22 and 32. The lifting control knobs (27, 37) are fixedly coupled to the upper ends of the lifting bolts (25, 35) that protrude upward through the horizontal bars (24, 34) to rotate the lifting bolts (25, 35) forward or reverse. make it possible The lifting rails (26, 36) are installed in pairs at regular intervals to the left and right from the lifting bolts (25, 35). The upper ends of the lifting rails (26, 36) are fixedly installed on the lower surfaces of the horizontal bars (24, 34), and the lower ends are fixedly installed on the surfaces of the plates (22, 32). And the lifting rails (26, 36) are installed through the guide holes (42, 52) of the lifting platforms (40, 50) to support the lifting of the lifting platforms (40, 50). The infrared radiation sensor module 110 is fixedly coupled to the front of the elevating platform (40, 50).

In addition, third rulers 28 and 38 are coupled to the inner surfaces of the vertical bars 23 and 33 in the vertical direction to check and adjust the height of the elevator bars 40 and 50.

In Figure 3, the first angle adjustment bracket 70 is coupled to the front of the second bed 60 to the first hinge protrusion 71 protruding and coupled to the second rail groove 12 of the first bed 10. The second hinge protrusion 72 is hinged to the first hinge shaft 73. And the second angle adjustment bracket 75 is a third hinge protrusion 76 protruding and coupled to the second rail groove 12 of the first bed 10 and a fourth hinge coupled to the side of the second bed 60. The protrusion 77 is hinged to the first hinge shaft 73. Moreover, the first hinge protrusion 71 is coupled to the second rail groove 12 of the first bed 10 so as to be movable or fixed, and the second hinge protrusion 72 is located on the front of the second bed 60. It is fixedly coupled, and the third hinge protrusion (76) is coupled to be movable or fixed to the second rail groove (12) of the first bed (10), and the fourth hinge protrusion (77) is coupled to the second bed (60). It is coupled to the side so that it can be moved or fixed.

In addition, a first ruler 13 is coupled to the surface of the first bed 10 in the horizontal direction so that the first infrared ray emitting device 20 can check the moving or fixed position on the first bed 10, and A second ruler 63 is coupled to the surface of the second bed 60 in the horizontal direction to check the moving or fixed position of the second infrared ray emitting device 30 on the second bed 60. The first ruler 13 and the second ruler 63 are calculated by varying approximately 1cm to approximately 1M in the field for testing. For example, when using an inspection device indoors, if the indoor measurement distance is 50cm, it is adjusted and calculated to be approximately 50M in the actual test field.

In FIG. 4, the first infrared radiation device 20 has a structure that is fixed or movable to the first bed 10, and the second infrared radiation device 30 has a structure that can be fixed or move to the second bed 60. am. That is, the fixing pieces 17 and 67 are respectively inserted into the first rail groove 11 of the first infrared radiation device 20 and the third rail groove 61 of the second infrared radiation device 30, and each plate Fixing bolts (15, 65) are coupled through the fixing holes (16, 66) formed in (22, 32) and the coupling holes (18, 68) formed in the fixing pieces (17, 67). The fixing bolts (15, 65) are screwed together with the coupling holes (18, 68) of the fixing pieces (17, 67). Therefore, the fixing bolts (15, 65) and the fixing pieces (17, 67) are screwed together so that the fixing bolts (15, 65) are rotated so that the fixing pieces (17, 67) are attached to the first rail of the plates (22, 32). By being in close contact with the inner upper surface of the groove 11 or the second rail groove 12, respectively, the first infrared ray emitting device 20 is fixed in close contact with the surface of the first bed 10, and the second infrared ray emitting device 20 is fixed to the surface of the first bed 10. (20) is tightly fixed to the surface of the second bed (60).

In Figure 5, the infrared radiation sensor module 110 is fixedly installed on the glass light emitting jig 124 in which the window glass room 122 is installed. In addition, the infrared radiation sensor module 110 is equipped with a built-in multi-layer hot plate 111 that generates and radiates multiple infrared wavelength bands by heating at a certain temperature, and an infrared wafer band filter 112 is installed on the surface of the window glass room 122. ) are combined. The infrared radiation sensor module 110 uses the infrared wafer band filter 112 to detect multiple infrared wavelengths generated by heating at approximately 850°C on the multi-layer hot plate 111, that is, approximately 1 to 15㎛ wavelength band (A). After creating the desired wavelength, that is, approximately 4.3 ~ 4.55㎛ wavelength band (B), the generated wavelength is used to irradiate the infrared sensor of the flame detector 90 to collect accurate data and verify it.

Meanwhile, the reason for applying the infrared wafer band filter 112 to the infrared radiation sensor module () is that the flame detector () with three infrared sensors has a main infrared sensor that sees fire and a main infrared sensor that sees fire and that it is not a fire. It uses two auxiliary infrared sensors. When data is detected by the main infrared sensor, if even one of the two auxiliary infrared sensors detects data, it is recognized that it is not a fire. The main infrared sensor has a bandwidth that can detect from a long distance, but the auxiliary infrared sensors have such low sensitivity that they can only detect at a short distance. In places where actual long-distance testing is performed, such as in a testing laboratory, testing is possible because only the main infrared sensor receives a lot of data and generates discrimination power. However, the flame detector performance smoothing test device of this design converts the actual long distance and is manufactured in a miniature form so that it can be used in a small space, so there is a situation in which both the main infrared sensor and the auxiliary infrared sensor detect the data emitted from the infrared radiation sensor. It happens. Therefore, to solve this problem, an infrared wafer band filter of the same band as the main infrared sensor is installed so that only the main infrared sensor, excluding the auxiliary infrared sensor, can detect data. Flame detectors can be set up more precisely by only detecting and reading data from the main infrared sensor.

In FIG. 6, the controller 100 is fixedly installed on the upper surface of the first bed 10 and operates the first infrared ray emitting device 20 or the second infrared radiating device 30, adjusts the amount of radiation, measures the transmittance, measures the amount of radiation, etc. It allows you to select and adjust. The front of the controller 100 is provided with a main power switch 101 that connects or cuts off the applied power, and a radiation device selection switch ( 102) is provided, a transmittance selection switch 103 is provided to measure the transmittance of the window glass 123, and a front radiation selection switch 104 is provided to select whether to operate the first infrared radiating device 20. , a side radiation selection switch 105 is provided to select whether to operate the second infrared radiation device 30. In addition, the front of the controller 100 is provided with a main radiation adjustment knob 106 for variably controlling the radiation amount of the first infrared radiation device 20 and the second infrared radiation device 30, and the first infrared radiation device 20 ) is provided with a front radiation control knob 107 for variably controlling the radiation amount of the second infrared ray emitting device 30, and a side radiation adjustment knob 108 for variably controlling the radiation amount of the second infrared ray emitting device 30, and the transmittance of the window glass 123. A transmittance radiation adjustment knob 109 is provided to variably control the radiation amount for measuring.

In FIG. 7, the flame detector 90 for smoothness inspection is installed with an infrared sensor inside the case 91 to detect irradiated infrared rays. Moreover, in FIG. 7A, three infrared sensors 92, 93, and 94 are installed in the flame detector 90. The three infrared sensors 92, 93, and 94 each receive infrared rays of different wavelength bands, allowing each product to receive different wavelength bands. The application of three infrared sensors (92, 93, and 94) to the flame detector (90) is applied to block disturbances such as human beings, animals, sunlight, halogen, etc. from a short distance along with the flame of a fire. Additionally, in FIG. 7B, the infrared sensor 95 and the ultraviolet sensor 96 may be installed together. This allows it to detect both infrared and ultraviolet rays.

Next, in FIG. 8, as a device for measuring the transmittance of the window glass 123 of the flame detector 90, the infrared radiation sensor module 110 is equipped with an infrared radiation sensor 121 in the glass light emitting jig 120. , a window glass room 122 is formed in the glass light emitting jig 120 of the infrared radiation sensor 121. The infrared sensor of the flame detector 90 is coupled to the glass light receiving jig 124. In measuring the transmittance of window glass, the infrared sensor of the flame detector 90 improves the detection efficiency of fire and has excellent detection performance of uniform and consistent data.

In addition, in Figure 9, when the infrared radiation sensor module 110 radiates infrared rays and the window glass 123 is not installed, the waveform RMS value of the infrared sensor is set to 10000 and the measured value of the infrared sensor is checked. When the RMS value is 9000, you can simply check the measured value as a transmission value of 90%. And the measurement value can be measured in 1/1000. After measuring infrared rays, if the transmission values of the window glass 123 are divided into groups and used, products with the same performance can be set up simply by modifying the software for operating the flame detector 90.

In Figure 10a, the transmittance when the window glass is not mounted on the flame detector 90 is 100%, but in Figure 10b, the transmittance when the window glass is mounted on the flame detector 90 is 90%. You can check it through .

Figure 11 shows the operation test method of the flame detector 90 performed by the Korea Fire Industry & Technology Institute. That is, Figure 11a is a test operated from the front of the flame detector 90. Here, to create a situation similar to an actual fire, a fire is ignited on a grill 130 measuring approximately 30 x 30 cm in width and height, and a flame detector 90 is placed at a distance of approximately 60 m. And install a screen (132) in front of the flame detector (90). Therefore, the time is measured at the same time as the fire of the grill 130 is ignited, and at approximately 1 minute, the screen 132 is removed and the time is measured for approximately 30 seconds. At this time, if it operates within approximately 30 seconds, it passes. The average value of data collected according to the operation of the flame detector 90 from the front is approximately 270 to 300. Figure 11b is a test operated from the side of the flame detector 90 and is performed under the same conditions as the front operation test. Side tests are collected from directions of 90° (45°) and 100° (50°) for each model of flame detector (90). At this time, if it operates within approximately 30 seconds, it passes. From the side, the average value of collected data according to the operation of the flame detector 90 is approximately 260 to 280. Therefore, the flame detector 90 must pass both the front and side tests to pass the operation test.

Figure 12 shows the non-operation test method of the flame detector 90 performed by the Korea Fire Industry & Technology Institute. The non-operation test is a test under which the flame detector 90 should not operate. Here, to create a situation similar to an actual fire, a fire is ignited on a fire plate (131) of approximately 15 x 15 cm in width and height, which is 1/4 the size of a fire plate for operation testing, and a flame detector (90) is installed at a distance of approximately 60 m. Position. And install a screen (132) in front of the flame detector (90). Therefore, the time is measured at the same time as the fire of the grill 131 is ignited, and when approximately 1 minute has elapsed, the screen 132 is removed and the time is measured for approximately 1 minute. At this time, if it operates within approximately 1 minute, it fails. In the non-operation test, the average value of collected data according to the operation of the flame detector 90 from the front is approximately 60 to 75. Therefore, the flame detector 90 must pass both the front and side tests to pass the non-operation test. If it passes all tests, it can be sold with a final pass sticker attached. Moreover, although type approval for a flame detector is obtained only once, products are always approved through the above-mentioned testing process and only products with a passing sticker attached are allowed to be sold.

In FIG. 13, a first infrared ray emitting device 20 is fixedly installed on the first bed 10, and a flame detector 90 is installed at a certain distance from the first infrared ray emitting device 20. And the second infrared radiation device 30 is fixedly installed on the second bed 60 installed at a certain angle on the side of the first bed 10. Then, set the same or similar conditions as the outdoor operation test performed by the Korea Fire Industry & Technology Institute and then perform the operation test indoors. That is, a front test of the flame detector 90 is performed with infrared rays emitted from the first infrared radiator 20, and a side test of the flame detector 90 is performed with infrared rays emitted from the second infrared radiator 30. do. In addition, a non-operation test of the flame detector 90 is also performed using the first infrared ray emitting device 20 and the second infrared ray emitting device 30 so that it can be judged by comparing it with the actual average value performed outdoors. At this time, the operation and non-operation tests are performed by adjusting the corresponding switches and knobs of the controller 100, and the data tested by the flame detector 90 is input to the controller 100 and converted into test data of the flame detector 90. Use it.

In the present invention, the above embodiment is an example and the present invention is not limited thereto. Anything that has substantially the same configuration and achieves the same effect as the technical idea described in the claims of the present invention is included in the technical scope of the present invention.

10: 1st bed 11: 1st rail groove 12: 2nd rail groove 13: 1st ruler 15, 65: fixing bolt 16, 66: fixing hole 17, 67: fixing piece 18, 68: coupling hole
20: first infrared radiation device 21, 31: housing 22, 32: plate 23, 33: vertical bar 24, 34: horizontal bar 25, 35: lifting bolt 26, 36: lifting rail 27, 37: lifting control knob 28, 38: Third ruler
30: Second infrared radiation device
40, 50: Elevating platform 41, 51: Elevating hole 42, 52: Guide hole
60: 2nd bed 61: 3rd rail groove 62: 4th rail groove 63: 2nd ruler
70: First angle adjustment bracket 71: First hinge projection 72: Second hinge projection 73: First hinge shaft 75: Second angle adjustment bracket 76: Third hinge projection 77: Fourth hinge projection 78: Second hinge shaft
80: Ultraviolet radiation device
90: Flame detector 91: Case 92, 93, 94, 95, 125: Infrared sensor 96: Ultraviolet sensor
100: Controller 101: Main power switch 102: Radiation device selection switch 103: Transmittance selection switch 104: Front radiation selection switch 105: Side radiation selection switch 106: Main radiation adjustment knob 107: Front radiation adjustment knob 108: Side radiation adjustment knob 109 : Transmittance radiation adjustment knob
110: Infrared radiation sensor module 111: Multilayer hot plate 112: Infrared wafer band filter
120: Glass light emitting jig 121: Infrared radiation sensor 122: Window glass room 123: Window glass 124: Glass light receiving jig
130, 131: Grill 132: Screen

Claims (10)

A first bed (10) that has a flat shape and has first rail grooves (11) formed at regular intervals in the horizontal direction on a plane, and second rail grooves (12) formed on the side in the horizontal direction;
A flame detector (90) fixedly coupled to one upper surface of the first bed (10);
A first infrared ray emitting device (20) movably or fixedly coupled to the first rail groove (11) of the first bed (10) and emitting infrared rays in a certain wavelength band to the flame detector (90);
It has a flat shape, and a third rail groove 61 is formed at regular intervals in the horizontal direction on the plane, and a fourth rail groove 62 is formed in the horizontal direction on the side, and at the side of the first bed 10. a second bed (60) coupled to the first bed (10) at a certain angle;
a second infrared radiation device 30 that is movably or fixedly coupled to the second rail groove 12 of the second bed 60 and radiates infrared rays in a certain wavelength band to the flame detector 90;
The second hinge protrusion 72 coupled to the front of the second bed 60 to the first hinge protrusion 71 protruding from the second rail groove 12 of the first bed 10 is connected to the first hinge axis. A first angle adjustment bracket (70) hinged at (73);
The fourth hinge protrusion 77 coupled to the side of the second bed 60 and the third hinge protrusion 76 protruding from the second rail groove 12 of the first bed 10 are connected to the first hinge shaft. A second angle adjustment bracket (75) hinged at (73);
A controller 100 that is fixedly installed on the upper surface of the first bed 10 and selects the operation, radiation amount control, transmittance measurement, and radiation amount measurement of the first infrared radiation device 20 or the second infrared radiation device 30; A flame detector performance smoothing test device comprising:
The method of claim 1, wherein a first ruler 13 is coupled to the surface of the first bed 10 in the horizontal direction, and a second ruler 63 is coupled to the surface of the second bed 60 in the horizontal direction. , Flame detector performance smoothing inspection device.
The method of claim 1, wherein the first hinge protrusion (71) is movably or fixedly coupled to the second rail groove (12) of the first bed (10), and the second hinge protrusion (72) is connected to the second rail groove (12) of the first bed (10). It is fixedly coupled to the front of (60),
The third hinge protrusion 76 is coupled to the second rail groove 12 of the first bed 10 so that it can be moved or fixed, and the fourth hinge protrusion 77 moves on the side of the second bed 60. Or a flame detector performance smoothing test device that can be combined for fixation.
The method of claim 1, wherein the first infrared radiation device 20 and the second infrared radiation device 30 are:
A pair of vertical bars (23, 33) are installed facing each other at regular intervals on the left and right on the flat plates (22, 32), and horizontal bars (24, 34) are installed horizontally at the top of the vertical bars (23, 33). Housings 21 and 31 installed integrally,
A lifting hole (41, 51) is formed at the center, and a pair of guide holes (42, 52) are formed at regular intervals from the lifting hole (41, 51), and the lifting hole (41, 51) is formed inside the housing (21, 31). Lifting platform (40, 50),
A lifting bolt (which is screwed to the lifting hole (41, 51), the upper end of which protrudes through the center of the horizontal bar (24, 34), and the lower end of which is fixedly installed at the center of the surface of the plate (22, 32) 25, 35) and,
Lifting control knobs (27, 37) that penetrate the horizontal bars (24, 34) and are fixedly coupled to the upper ends of the lifting bolts (25, 35) that protrude upward;
It is installed at regular intervals to the left and right from the lifting bolts (25, 35), and the upper part is fixed to the lower surface of the horizontal bar (24, 34), and the lower part is fixed to the surface of the plate (22, 32) , a pair of elevating rails (26, 36) installed through the guide holes (42, 52) to support the elevating and lowering of the elevating platforms (40, 50),
A flame detector performance smoothing inspection device comprising an infrared radiation sensor module (110) fixedly coupled to the front of the elevating platform (40, 50).
The flame detector performance smoothing inspection device according to claim 4, wherein a third ruler (28, 38) is coupled to the inner surface of the vertical stand (23, 33) in the vertical direction.
The method of claim 4, wherein the first infrared radiation device (20) has a fixing piece (17) inserted into the first rail groove (11), and a fixing hole (16) and a fixing piece (17) formed in the plate (22). ) is penetrated through the coupling hole 18 formed in the fixing bolt 15 and the fixing piece 17, including a fixing bolt 15 screwed with the coupling hole 18 of the fixing piece 17. The plate 22 is closely coupled to the surface of the first bed 10, and the second infrared ray emitting device 30 has a fixing piece 67 inserted into the third rail groove 61, and the plate ( It is coupled through the fixing hole 66 formed in the fixing hole 66 and the coupling hole 68 formed in the fixing piece 67, and includes a fixing bolt 65 screwed to the coupling hole 68 of the fixing piece 67. A flame detector performance smoothing test device in which the plate 32 is closely coupled to the surface of the first bed 10 by screwing the fixing bolt 65 and the fixing piece 67.
The method of claim 4, wherein the infrared radiation sensor module 110 is fixed to a glass light emitting jig 121 in which a window glass room 120 is installed, and is a multi-layer device that generates and radiates multiple infrared wavelength bands by heating at a certain temperature. A flame detector performance smoothing inspection device in which a hot plate (111) is built-in and an infrared wafer band filter (112) is coupled to the surface of the window glass room (120).
The flame detector performance smoothing inspection device according to claim 7, wherein the infrared wafer band filter (112) filters the 1-15㎛ wavelength band generated by the multi-layer hot plate (111) into the 4.3-4.55㎛ wavelength band.
The method of claim 1, wherein the controller 100,
A main power switch (101) that connects or blocks the applied power,
A radiation device selection switch (102) for selecting the first infrared radiation device (20) or the second infrared radiation device (30),
A transmittance selection switch 103 that measures the transmittance of the window glass 123,
A front radiation selection switch (104) that selects whether to operate the first infrared radiation device (20),
A side radiation selection switch (105) that selects whether to operate the second infrared radiation device (30),
A main radiation adjustment knob (106) for variably controlling the radiation amount of the first infrared radiation device (20) and the second infrared radiation device (30),
A front radiation adjustment knob (107) that variably controls the radiation amount of the first infrared radiation device (20),
A side radiation adjustment knob (108) for variably controlling the radiation amount of the second infrared radiation device (30),
A flame detector performance smoothing test device including a transmittance radiation adjustment knob (109) for variably controlling the radiation amount for measuring the transmittance of the window glass (123).
The flame detector performance smoothing inspection device according to claim 1, wherein the flame detector (90) is equipped with a single or a plurality of infrared sensors or an infrared sensor and an ultraviolet sensor.