JP5322713B2 - Monitoring device - Google Patents

Description

  The present invention relates to a monitoring device for monitoring a facility to be monitored such as a plant or a factory, and more particularly to a pressure-proof explosion-proof monitoring device for monitoring a dangerous place.

  In an anomaly monitoring system that constantly monitors whether a facility such as a plant or factory is operating normally, a remotely operable industrial camera installed in the facility to be monitored is widely used. In addition to a camera that captures an image in a monitoring target facility, a monitoring device including a microphone that detects sound in the monitoring target facility is also known (see, for example, Patent Document 1). Wireless transmission is widely used for transmission and reception of signals between the monitoring apparatus and the main station in such an abnormality monitoring system.

  In order to install such an abnormality monitoring system in a dangerous place under the Fire Service Law, it is necessary to make the equipment installed in the dangerous place a pressure-proof explosion-proof structure in order to prevent an explosion accident. Here, the dangerous place is a place where flammable gas or flammable liquid vapor may exist, for example, an explosion-proof area of an oil plant. In addition, the explosion-proof structure is a structure in which when a flammable gas explosion occurs inside a fully-closed container, the container can withstand the pressure and there is no risk of igniting external explosive gas.

  In order to be certified as an explosion-proof device that can be installed in a hazardous area, it is necessary to pass a predetermined certification test.

JP-A-9-196825

  However, in the conventional abnormality monitoring system, devices such as cameras, microphones, and wireless devices installed in hazardous areas need to have an explosion-proof structure, and the monitoring apparatus including these devices is increased in size and weight. It was difficult to avoid. For this reason, the conventional monitoring device is inferior in portability, and it is not easy to change the monitoring location in the monitoring target facility.

  An object of the present invention is to provide a pressure- and explosion-proof monitoring device that is small, lightweight, excellent in portability, and capable of easily changing a monitoring location.

The purpose is to capture a picture having an explosion-proof structure, a microphone built in the casing for detecting sound in the monitoring target equipment, and an image in the monitoring target equipment built in the casing. A camera, an information processor for controlling sound data from the microphone and image data from the camera, and controlling the microphone and the camera, and being processed by the information processor. A monitoring device having a radio for transmitting the acoustic data and the image data and receiving control signals for the microphone and the camera, and an antenna built in the housing and connected to the radio The housing includes a radio wave transmission / reception window having radio wave permeability, and a portion where the radio wave transmission / reception window is provided is the monitoring unit. Are formed by downward inclined side of device, the antenna is achieved by monitoring apparatus characterized by transmitting and receiving radio waves through the transmitting and receiving radio waves window.

  In the monitoring apparatus described above, the housing includes an acoustic detection window made of an air-permeable structural material having air permeability, and the microphone detects sound in the monitoring target facility through the acoustic detection window. May be.

  In the monitoring device described above, the air-permeable structural member may be made of a metal porous body.

  In the monitoring device described above, a mesh provided to provide a waterproof property to the sound detection window or a thin plate to provide dustproof and waterproof properties to the sound detection window is further provided on the front surface or the rear surface of the breathable structure material. You may make it have.

  The monitoring apparatus described above may further include a radio wave reflector that is provided in the casing, reflects radio waves incident on the casing through the radio wave transmission / reception window, and reflects radio waves radiated from the antenna. .

  In the monitoring apparatus described above, the antenna is a pole-type antenna, and the radio wave reflector has a partial cylindrical shape, and the open side thereof faces the radio wave transmission / reception window side so as to surround the antenna along the antenna. It may be made to face.

According to the present invention, a microphone for detecting sound in a monitoring target facility, a camera for capturing an image in the monitoring target facility, acoustic data from the microphone and a camera in a housing having a pressure-proof explosion-proof structure. An information processing device for processing image data and controlling the microphone and the camera; a radio device for transmitting acoustic data and image data processed by the information processing device and receiving control signals for the microphone and camera; , Built- in antenna connected to the radio, and the housing has a radio wave transmission / reception window having radio wave permeability, and the portion provided with the radio wave transmission / reception window is formed to be inclined downward to the side of the monitoring device is the antenna. Thus for transmitting and receiving radio waves through the transmitting and receiving radio waves windows, highly portable small and lightweight, to easily change the monitoring location It is possible, it is possible to provide a monitoring device for Explosion-proof capable of transmitting and receiving radio waves in a wide angular range.

It is the schematic which shows the structure of the abnormality monitoring system by 1st Embodiment of this invention. It is the schematic which shows the structure of the monitoring apparatus by 1st Embodiment of this invention. It is a perspective view which shows the flameproof enclosure of the monitoring apparatus by 1st Embodiment of this invention. It is the schematic which shows the specific structure of the monitoring apparatus by 1st Embodiment of this invention. It is the schematic which shows the specific structure of the acoustic detection window and image pick-up window of the monitoring apparatus by 1st Embodiment of this invention. It is the schematic which shows the specific structure of the antenna part of the monitoring apparatus by 1st Embodiment of this invention. It is the schematic which shows reflection of the electromagnetic wave in the antenna part of the monitoring apparatus by 1st Embodiment of this invention. It is a graph which shows the frequency spectrum of the acoustic data detected with the microphone of the monitoring apparatus by 1st Embodiment of this invention. It is the schematic which shows the structure of the monitoring apparatus by 2nd Embodiment of this invention. It is the schematic which shows the specific structure of the monitoring apparatus by 2nd Embodiment of this invention. It is a graph which shows the frequency spectrum obtained as a result of detecting the sound of frequency 1000Hz with the microphone of the monitoring apparatus which provided the drip-proof member or the waterproofing member in the front surface of the porous plate-shaped structure material. It is the schematic which shows the structure of the monitoring apparatus by 3rd Embodiment of this invention. It is the schematic which shows the specific structure of the monitoring apparatus by 3rd Embodiment of this invention.

[First Embodiment]
A monitoring apparatus according to a first embodiment of the present invention and an abnormality monitoring system using the same will be described with reference to FIGS. FIG. 1 is a schematic diagram illustrating the configuration of an abnormality monitoring system according to the present embodiment, FIG. 2 is a schematic diagram illustrating the configuration of a monitoring device according to the present embodiment, and FIG. 3 is a perspective view illustrating a flameproof enclosure of the monitoring device according to the present embodiment. 4 is a schematic diagram illustrating a specific structure of the monitoring device according to the present embodiment, FIG. 5 is a schematic diagram illustrating a specific structure of an acoustic detection window and an image capturing window of the monitoring device according to the present embodiment, and FIG. 7 is a schematic diagram showing a specific structure of the antenna unit of the monitoring device according to the embodiment, FIG. 7 is a schematic diagram showing reflection of radio waves at the antenna unit of the monitoring device according to the embodiment, and FIG. 8 is a microphone of the monitoring device according to the embodiment. It is a graph which shows the frequency spectrum of the detected acoustic data.

  First, the abnormality monitoring system according to the present embodiment will be described with reference to FIG. The abnormality monitoring system according to the present embodiment is for notifying an abnormality by monitoring leakage of equipment, piping, etc. in a facility to be monitored such as a refinery or a malfunction of a rotating machine.

  As shown in FIG. 1, a monitoring device 10 for monitoring the monitored facility, a wireless main station 12, and a wireless repeater 14 are installed in an explosion-proof area of the monitored facility such as a refinery. . In addition, in a non-explosion-proof area such as a measurement room, a monitoring processing device for managing and processing acoustic data and image data, which are monitoring data collected by the monitoring device 10, and for controlling the monitoring device 10 16 is installed. A wireless main station 12 is connected to the monitoring processing device 16 via a cable.

  The monitoring data collected by the monitoring device 10 is wirelessly transmitted to the wireless main station 12 via the wireless repeater 14 and transmitted to the monitoring processing device 16. The control signal of the monitoring device 10 output from the monitoring processing device 16 is transmitted from the wireless main station 12 and wirelessly transmitted to the monitoring device 10 via the wireless repeater 14.

  Next, the monitoring apparatus 10 according to the present embodiment used in the abnormality monitoring system shown in FIG. 1 will be described with reference to FIGS.

  The monitoring apparatus 10 according to the present embodiment is of an explosion-proof type, and as shown in FIG. 2, an explosion-proof enclosure 18, a microphone 20 for detecting sound in the monitored equipment, and an image in the monitored equipment. Information processing device 24 for performing processing on the sound data from the camera 22 and the microphone 20 and image data from the camera 22 and controlling the microphone 20 and the camera 22, and the sound data from the information processing device 24. A radio 26 for transmitting image data and receiving control signals for the microphone 20 and the camera 22, a pole antenna 28 as an antenna of the radio 26, and a radio wave reflector provided for the pole antenna 28 30. The microphone 20, the camera 22, the information processing device 24, the wireless device 26, the pole antenna 28, and the radio wave reflector 30 are all built in the flameproof enclosure 18.

  The explosion-proof enclosure 18 is a flame-proof enclosure that is made of a metal material such as an aluminum alloy material that satisfies the explosion-proof specification. The explosive gas explodes in the enclosure and the pressure in the enclosure is increased. Even if it rises, it will not be damaged. As shown in FIG. 3, the explosion-proof enclosure 18 has a main body portion 18a having an upper surface in which a device such as a microphone 20 is accommodated and an upper surface opening of the main body portion 18a fixed to the main body portion 18a by screws or the like. The upper lid portion 18b is closed. A sound detection window 32 and an image capturing window 34 are provided on the front wall 18c of the main body 18a, and a radio wave transmission / reception window 36 is provided on the upper lid 18b.

  FIG. 4 shows a specific structure of the monitoring apparatus 10 according to the present embodiment. 4A is a front view of the monitoring device 10, and FIG. 4B is a side sectional view of the monitoring device 10. FIG. 4 shows a case where the camera 22 is configured by a commercially available network camera including a circuit unit (not shown) that functions as the information processor 24 shown in FIG.

  As shown in FIG. 4, the microphone 20 and the camera 22 in the explosion-proof enclosure 18 are arranged so as to face the front wall portion 18 c of the explosion-proof enclosure 18. A sound detection window 32 for detecting sound in the monitoring target facility by the microphone 20 is provided in the front wall portion 18 c in front of the microphone 20 of the flameproof enclosure 18. In addition, an image capturing window 34 for capturing an image of the monitoring target facility by the camera 22 is provided in the front wall 18c of the explosion-proof enclosure 18 in front of the camera 22.

  The sound detection window 32 is configured by a porous plate-like structural member 40 attached to the opening 38 of the front wall 18c of the explosion-proof enclosure 18. The porous plate-like structural member 40 is made of, for example, a metal porous body having a three-dimensional network structure like a sponge and having a large number of pores communicating with the inside. The metal porous body is made of, for example, nickel, nickel-chromium alloy, stainless steel, cobalt alloy, titanium alloy, or the like. Further, the porous metal body has a porosity of, for example, 88 to 98%, and the number of cells partitioned by the skeleton of the three-dimensional network structure is, for example, 10 to 50 / inch, and has sufficient mechanical strength, It has sufficient air permeability. The acoustic detection window 32 configured using the porous plate-like member 40 made of such a metal porous body satisfies the explosion-proof specification, and the sound in the monitored facility propagates inside the explosion-proof casing 18. Can be done. Thus, in the monitoring apparatus 10 according to the present embodiment, the sound in the monitored facility can be detected by the microphone 20 through the sound detection window 32 without impairing the explosion-proof performance.

  As described above, the monitoring device 10 according to the present embodiment has one of the main features in that it has the acoustic detection window 32 configured using the porous plate-like structural member 40 made of a metal porous body.

  The explosion-proof enclosure 18 is made of a thick metal material to satisfy the explosion-proof specification. If no opening is provided in the explosion-proof enclosure 18, the sound propagates due to the vibration of air, so that the sound cannot propagate into the explosion-proof enclosure 18. As a result, the microphone 20 in the explosion-proof enclosure 18 cannot detect sound in the monitored facility. On the other hand, if the explosion-proof enclosure 18 is simply provided with only an opening, the explosion-proof enclosure 18 cannot satisfy the explosion-proof specification.

  In this regard, in the monitoring apparatus 10 according to the present embodiment, the acoustic detection window 32 configured using the porous plate-like structural member 40 made of a metal porous body is provided in the explosion-proof enclosure 18. For this reason, the sound in the monitoring target equipment can be detected by the microphone 20 through the sound detection window 32 without impairing the explosion-proof performance.

  The image capturing window 34 is configured by a pressure-resistant glass plate 44 that transmits visible light attached to the opening 42 of the front wall portion 18 c of the flame-proof enclosure 18. The image capturing window 34 constituted by the pressure-resistant glass plate 44 has visible light permeability and satisfies the pressure-proof explosion-proof specification. Thus, in the monitoring apparatus 10 according to the present embodiment, an image in the monitoring target facility can be captured by the camera 22 through the image capturing window 34 without impairing the explosion-proof performance.

  FIG. 5 shows an example of a specific structure of the acoustic detection window 32 and the image capturing window 34. FIG. 5A is a front view of the monitoring device 10, and FIG. 5B is a side sectional view of the monitoring device 10.

  As shown in FIG. 5, the acoustic detection window 32 is configured by fixing the porous plate-like structural member 40 to the front wall portion 18 c from the outside of the explosion-proof enclosure 18 by a fixing jig 46. The opening 38 of the front wall 18c is closed by a porous plate-like structural member 40 fixed by a fixing jig 46.

  The image capturing window 34 is configured such that a pressure-resistant glass plate 44 is fixed to the front wall portion 18 c by a fixing jig 48 from the outside of the flame-proof enclosure 18. The opening 42 of the front wall 18c is closed by a pressure-resistant glass plate 44 fixed by a fixing jig 48.

  Thus, the explosion-proof enclosure 18 is provided with the acoustic detection window 32 and the image capturing window 34 for the built-in microphone 20 and camera 22 without impairing the explosion-proof performance.

  The information processing device 24 controls sound detection by the microphone 20 and image capturing by the camera 22 based on a control signal wirelessly transmitted from the monitoring processing device 16. Further, the information processing device 24 performs various processes such as a compression process and a protocol process on the acoustic data detected by the microphone 20 and the image data captured by the camera 22. The information processing device 24 is connected to the wireless device 26 via, for example, a LAN cable.

  When the camera 22 is configured by a commercially available network camera (see FIG. 4), the network camera includes a circuit unit (not shown) that functions as the information processing device 24. A microphone 20 is connected to the network camera constituting the camera 22. In addition, as a network camera constituting the camera 22, a type having a built-in microphone 20 may be used.

  The wireless device 26 receives a control signal of the monitoring device 10 wirelessly transmitted from the monitoring processing device 16 and transmits the control signal to the information processing device 24, and acoustic data and image data subjected to various processes by the information processing device 24. Is transmitted to the monitoring processor 16. A pole antenna 28 is connected to the wireless device 26 via a cable. The radio device 26 transmits acoustic data and image data and receives control signals via the pole antenna 28.

  In the explosion-proof enclosure 18, as shown in FIG. 4, a power supply unit for supplying power to devices in the explosion-proof enclosure 18 such as a radio 26 or a camera 22 constituted by a network camera. 27 is built-in.

  As the pole antenna 28, for example, a pencil antenna is used, and its gain is, for example, 2 dB. The pole antenna 28 in the explosion-proof enclosure 10 is disposed in the vicinity of the upper lid portion 18b of the explosion-proof enclosure 18. A radio wave transmission / reception window 36 for transmitting / receiving radio waves by the pole antenna 28 is provided on the upper lid portion 18b of the explosion-proof enclosure 18 along a pole antenna 28 disposed in the vicinity thereof.

  For example, two pole antennas 28 are arranged in parallel along the front-rear direction of the monitoring device 10, and a radio wave transmission / reception window 36 is provided for each. In this case, the upper lid portion 18b of the explosion-proof explosion-proof housing 18 is inclined downward toward the side of the monitoring device 10 (see FIGS. 3 and 4). Thereby, the pole-type antenna 28 in the explosion-proof enclosure 10 can transmit and receive radio waves in a wide angle range.

  The radio wave transmission / reception window 36 is constituted by a pressure-resistant glass plate 52 that transmits radio waves attached to the opening 50 of the upper lid portion 18b of the flameproof enclosure 18. The radio wave transmission / reception window 36 composed of the pressure-resistant glass plate 52 has radio wave permeability and satisfies the pressure-proof explosion-proof specification. Thus, in the monitoring device 10 according to the present embodiment, the acoustic data from the microphone 20 and the image data from the camera 22 are transmitted from the pole antenna 28 to the monitoring processing device 16 through the radio wave transmission / reception window 36 without impairing the explosion-proof performance. The control signal wirelessly transmitted from the monitoring processor 16 can be received by the pole antenna 28.

  In the explosion-proof enclosure 18, a metal radio wave reflecting plate 30 that reflects radio waves is provided for the pole antenna 28. FIG. 6A is a cross-sectional view showing the pole antenna 28 and the radio wave reflector 30, and FIG. 6B is a perspective view showing the pole antenna 28 and the radio wave reflector 30.

  As shown in FIG. 6, a metal radio wave reflector 30 having a partial cylindrical shape is provided around the pole antenna 28 so as to surround the pole antenna 28 along the pole antenna 28. The radio wave reflector 30 is attached to the inner portion of the upper lid portion 18b including the radio wave transmission / reception window 36 with the open side thereof facing the radio wave transmission / reception window 36 side. The radius of the partial cylindrical shape of the radio wave reflector 30 is preferably about ¼ wavelength of radio waves used for wireless transmission between the monitoring device 10 and the monitoring processing device 16. The distance of the reflecting plate 30 is 1/6 to 1/3 wavelength of the radio wave used for wireless transmission, and preferably 1/6 to 1/4 wavelength.

  As described above, the monitoring apparatus 10 according to the present embodiment is also mainly characterized in that the partial antenna-shaped radio wave reflector 30 is provided for the pole antenna 28 built in the explosion-proof enclosure 18. There is one.

  Since the pole type antenna 28 is smaller than the planar antenna, the pole type antenna 28 can be built in the explosion-proof enclosure 18 without causing an increase in the size of the explosion-proof enclosure 18. However, it is difficult to transmit and receive radio waves with high efficiency by using the pole antenna 28 built in the explosion-proof enclosure 18 as it is.

  In this regard, in the monitoring apparatus 10 according to the present embodiment, a partially cylindrical radio wave reflector 30 is provided for the pole antenna 28 built in the explosion-proof enclosure 18.

  Of the radio waves incident on the explosion-proof enclosure 18 through the radio wave transmission / reception window 36, the radio waves not directly received by the pole antenna 28 are reflected by the radio wave reflector 30 in the direction toward the pole antenna 28. Is received. In this way, the radio wave incident on the explosion-proof enclosure 18 through the radio wave transmission / reception window 36 can be received by the pole antenna 28 with high efficiency.

  Also, of the radio waves radiated from the pole antenna 28, the radio waves radiated in directions other than the direction toward the radio wave transmission / reception window 36 are directed in the direction toward the radio wave transmission / reception window 36 by the radio wave reflector 30 as shown in FIG. Reflected. In this way, radio waves can be transmitted from the pole antenna 28 with high efficiency to the outside of the explosion-proof enclosure 18 through the radio wave transmission / reception window 36.

  As described above, in the monitoring apparatus 10 according to the present embodiment, since the radio wave reflector 30 is provided for the pole antenna 28, radio waves can be transmitted and received with high efficiency, and radio waves with a wide directivity can be obtained. Can be sent and received. In addition, since the radius of the partial cylindrical shape of the radio wave reflector 30 is set to be smaller than a quarter wavelength of the radio wave, radio waves can be transmitted and received with a wider directivity.

  Further, the radio wave reflector 30 does not have a parabolic reflecting surface like a parabolic antenna, but has a partial cylindrical shape that can be easily processed in engineering. Therefore, it is possible to easily prepare a radio wave reflecting plate 30 having an appropriate reflecting surface according to the characteristics of the pole antenna 28 to be used.

  As described above, the monitoring apparatus 10 according to the present embodiment incorporates the microphone 20, the camera 22, the information processing device 24, the wireless device 26, the pole antenna 28, and the radio wave reflector 30 in the explosion-proof enclosure 18. It has the main feature in doing.

  The monitoring device 10 according to the present embodiment incorporates all the devices such as the microphone 20 in a single explosion-proof explosion-proof casing 18, and thus is smaller and lighter than a conventional explosion-proof monitoring device. It has become. For this reason, the monitoring apparatus 10 according to the present embodiment is excellent in portability, can be carried by hand, and can easily change the installation location. Further, for example, it can be easily installed at a place where it was difficult to install in the past, such as the second floor in the facility to be monitored.

  In addition, the monitoring apparatus 10 according to the present embodiment can be configured at low cost because the pressure-proof explosion-proof structure is realized with a simple structure using the single pressure-proof explosion-proof casing 18 as described above.

  In addition, until now, abnormalities in monitoring target facilities have often been detected by the visual and auditory sense of on-site patrolmen who patrol and monitor the monitored target facilities. However, it is practically difficult for the on-site patrol staff to constantly monitor the inside of the monitoring target facility.

  On the other hand, the monitoring apparatus 10 according to the present embodiment uses the acoustic data detected by the microphone 20 through the acoustic detection window 32 and the image data captured by the camera 22 through the image imaging window 32. Can be constantly monitored. Therefore, the monitoring apparatus 10 according to the present embodiment can reliably detect an abnormality in the monitoring target facility.

  Furthermore, the monitoring device 10 according to the present embodiment is controlled by a control signal wirelessly transmitted from the monitoring processing device 16 installed in a non-explosion-proof area such as a measurement room away from the monitoring location, and monitors the collected monitoring data. Wireless transmission to the device 16. Therefore, a cable for transmitting a control signal to the monitoring device 10 according to the present embodiment and a cable for transmitting monitoring data from the monitoring device 10 to the monitoring processing device 16 are unnecessary. For this reason, the monitoring apparatus 10 by this embodiment can change an installation place easily.

  Next, an abnormality monitoring method for a monitoring target facility using the abnormality monitoring system according to the present embodiment will be described with reference to FIGS.

  The monitoring processing device 16 installed in a non-explosion-proof area such as an instrument room wirelessly transmits the control signal of the monitoring device 10 to the monitoring device 10 via the wireless main station 12 and the wireless repeater 14. The control signal includes a setting signal for the microphone 20 and the camera 22 of the monitoring device 10, a control signal for driving the camera 22 in the horizontal direction and the vertical direction, monitoring model information of the monitoring device 10, and the like.

  The control signal wirelessly transmitted from the monitoring processing device 16 is received by the wireless device 26 via the pole antenna 28 in the monitoring device 10 installed in the explosion-proof area of the monitoring target facility. The control signal received by the wireless device 26 is transmitted to the information processing device 24.

  The information processing device 24 controls sound detection by the microphone 20 and image capturing by the camera 22 based on information of a control signal transmitted from the wireless device 26. In this way, the monitoring target facility is constantly monitored by detecting the sound in the monitoring target facility with the microphone 20 and capturing an image with the camera 22.

  When monitoring the monitoring target facility, the monitoring device 10 is continuously installed at a specific location, and the location where the monitoring device 10 is installed may be changed regularly or irregularly as necessary. In addition, for example, the monitoring device 10 is installed in a place where the necessity of monitoring is considered to be particularly high depending on the situation in the monitoring target facility. As described above, the monitoring device 10 is small, lightweight, and excellent in portability, and a cable for transmitting monitoring data and control signals is not required between the monitoring device 10 and the monitoring processing device 16. is there. For this reason, in the abnormality monitoring system according to the present embodiment, the location where the monitoring device 10 is installed can be easily changed as necessary.

  The acoustic data detected by the microphone 20 of the monitoring device 10 and the image data picked up by the camera 22 are subjected to various processing such as compression processing and protocol processing by the information processing device 24 and then the pole type antenna by the wireless device 26. 28.

  The acoustic data and the image data transmitted from the monitoring device 10 in this way are wirelessly transmitted to the wireless main station 12 via the wireless repeater 14.

  The sound data and image data transmitted to the wireless main station 12 are transmitted to the monitoring processing device 16 via a cable.

  In the monitoring processing device 16, management and processing of the acoustic data and image data collected by the monitoring device 10 are performed. That is, the monitoring processing device 16 compares the image data collected by the monitoring device 10 with a comparison image stored in advance and detects a change in the image, thereby monitoring an abnormality of the monitoring target equipment. In addition, the monitoring processing device 16 calculates a frequency spectrum from the acoustic data collected by the monitoring device 10 and detects the occurrence of an abnormality in the monitoring target facility using a neural network model.

  FIG. 8 shows the frequency spectrum of the acoustic data detected by the monitoring apparatus 10 according to the present embodiment. In the graph, the solid line spectrum indicates the frequency spectrum of normal sound. Moreover, the spectrum of a broken line is a frequency spectrum of the gas leak sound which is one of the abnormal sounds in the monitoring target equipment.

  As is apparent from the spectrum shown in FIG. 8, according to the monitoring apparatus 10 according to the present embodiment, the gas leak sound can be detected and detected from the normal sound by the microphone 20 in the explosion-proof enclosure 18. I understand.

  When the monitoring processing device 16 detects an abnormality based on the acoustic data and image data collected by the monitoring device 10, the monitoring processing device 16 notifies the operator of the abnormality by a display indicating the occurrence of the abnormality, an alarm by a contact signal, or the like.

  As described above, according to the present embodiment, a device such as the microphone 20 is built in the explosion-proof enclosure 18, the monitoring device 10 is small, lightweight, and excellent in portability. Since a cable for transmitting a control signal and a cable for transmitting monitoring data from the monitoring device 10 to the monitoring processing device 16 are not required, the location where the monitoring device 10 is installed can be easily changed.

[Second Embodiment]
A monitoring device according to a second embodiment of the present invention will be described with reference to FIGS. 9 is a schematic diagram showing the configuration of the monitoring device according to the present embodiment, FIG. 10 is a schematic diagram showing the specific structure of the monitoring device according to the present embodiment, and FIG. 11 is a drip-proof member on the front surface of the porous plate-shaped structural material. Or it is a graph which shows the frequency spectrum obtained as a result of detecting the sound of frequency 1000Hz with the microphone of the monitoring apparatus which provided the member for waterproofing. In addition, the same code | symbol is attached | subjected about the component similar to the monitoring apparatus by 1st Embodiment, and the abnormality monitoring system using the same, and description is abbreviate | omitted or simplified.

  The monitoring device 54 according to the present embodiment is a mesh 56 as a drip-proof member for imparting drip-proof property to the sound detection window 32 or a waterproof member for imparting waterproof property to the monitoring device 10 according to the first embodiment. The main feature is that it has further.

  As shown in FIG. 9, the acoustic detection window 32 in the monitoring device 54 according to the present embodiment further includes a mesh 56 provided on the front surface of the porous plate-like structural member 40.

  FIG. 10 shows a specific structure of the monitoring device 54 according to the present embodiment. 10A is a front view of the monitoring device 54, and FIG. 10B is a side sectional view of the monitoring device 54. 10 shows a case where the camera 22 is configured by a commercially available network camera including a circuit unit (not shown) that functions as the information processing device 24, as in FIG.

  As shown in FIG. 10, the acoustic detection window 32 in the monitoring device 54 according to the present embodiment includes a porous plate-like structural member 40 attached to the opening 38 of the front wall portion 18 c of the explosion-proof enclosure 18, and a porous structure. It is comprised by the mesh 56 provided in the front surface of the plate-shaped structure material 40 so that the porous plate-shaped structure material 40 might be covered.

  The mesh 56 is a drip-proof member for imparting drip-proof properties to the sound detection window 32 or a waterproof member for imparting waterproof properties without hindering the propagation of sound into the explosion-proof explosion-proof casing 18. . The mesh 56 is, for example, a metal mesh. The mesh size of the mesh 56 is, for example, 100 mesh or more, specifically 200 mesh. Since the propagation of sound into the explosion-proof enclosure 18 is not hindered by the mesh 56, the sound in the monitored facility can be detected by the microphone 20 in the explosion-proof enclosure 18. The mesh size of 100 meshes means that the number divided between 1 inch (25.4 mm) is 100.

  Here, a mesh having a mesh size of 100 mesh is used in so-called life waterproofing corresponding to JIS waterproofing protection class 4 which is defined as being not adversely affected by water splash from any direction. Compared with a mesh having a mesh size of 100 mesh, a mesh having a mesh size of 200 mesh is twice as fine as a mesh. Therefore, by providing the mesh 56 having a mesh size of 200 mesh on the front surface of the porous plate-like structural member 40, the acoustic detection window 32 can be made more waterproof than life waterproof.

  Thus, in the monitoring device 54 according to the present embodiment, since the mesh 56 is provided on the front surface of the porous plate-like structural member 40, the acoustic detection window 32 is drip-proof or waterproof. Therefore, liquid such as moisture can be prevented from entering the explosion-proof enclosure 18 from the acoustic detection window 32. As a result, the monitoring device 54 according to the present embodiment can monitor the abnormality of the monitoring target equipment while protecting the device such as the microphone 20 in the explosion-proof enclosure 18 from the liquid such as moisture. According to the monitoring device 54 according to the present embodiment, for example, it is possible to monitor abnormality of a monitoring target facility that may cause liquid splash.

  In addition, instead of the mesh 56, a metal or resin thin plate is used as a porous plate-like structure as a drip-proof member for imparting drip-proof properties to the acoustic detection window 32 or a waterproof member for imparting waterproof properties. The front surface of the material 40 may be provided so as to cover the porous plate-like structure material 40. The sound detection window 32 is provided with a dustproof property in addition to a dripproof property or a waterproof property by the thin plate provided on the front surface of the porous plate-shaped structural member 40. In this case, the thickness of the thin plate is set according to the material so that the sound in the monitoring target facility can be detected by the microphone 20 without the propagation of the sound into the explosion-proof enclosure 18 being prevented. For example, for an aluminum thin plate, the thickness is set to 0.05 mm, for example.

  FIG. 11 is a graph showing a frequency spectrum obtained as a result of detecting a sound having a frequency of 1000 Hz by the microphone 20 of the monitoring device in which a drip-proof member or a waterproof member is provided on the front surface of the porous plate-like structural member 40.

  FIG. 11 shows the detection results when various drip-proof members (waterproof members) are provided, as well as the detection results when the drip-proof members (waterproof members) are not provided. The spectrum indicated by ● indicates the result when no drip-proof member is provided on the front surface of the porous plate-like structural member 40. The spectrum indicated by □ shows the result when a mesh having a mesh size of 200 mesh is provided as a drip-proof member. The spectrum indicated by ▲ shows the result when a thin aluminum plate having a thickness of 0.05 mm is provided as a drip-proof member. The spectrum indicated by ◯ shows the result when a thin plate made of ABS resin having a thickness of 0.3 mm is provided as a drip-proof member. The spectrum indicated by ◆ shows the result when a thin aluminum plate having a thickness of 0.5 mm is provided as a drip-proof member. For these cases, the peak value of sound pressure in the obtained spectrum was determined.

  When the drip-proof member indicated by ● was not provided, the peak value of the sound pressure was 40.1 dB.

  When a mesh having a mesh size of 200 mesh indicated by □ was provided, the peak value of sound pressure was 38.8 dB, and the difference from the case where no drip-proof member was provided was −1.3 dB.

  When an aluminum thin plate having a thickness of 0.05 mm indicated by ▲ is provided, the peak value of the sound pressure is 37.8 dB, and the difference from the case where no drip-proof member is provided is -2.3 dB. .

  When a thin sheet made of ABS resin with a thickness of 0.3 mm indicated by ○ is provided, the peak value of the sound pressure is 32.7 dB, and the difference from the case where no drip-proof member is provided is −7.4 dB. It was.

  When an aluminum thin plate having a thickness of 0.5 mm indicated by ◆ is provided, the peak value of the sound pressure is 30.4 dB, and the difference from the case where no drip-proof member is provided is −9.7 dB. .

  In addition, although not shown in FIG. 11, when a copper thin plate (copper foil) is provided as a drip-proof member on the front surface of the porous plate-like structural member 40, a vinyl chloride resin thin plate is provided, In the case of providing a thin plate made of styrene resin, sound having a frequency of 1000 Hz was detected in the same manner as described above, and the peak value of sound pressure in the obtained frequency spectrum was obtained.

  When a thin copper plate having a thickness of 0.01 mm was provided, the peak value of the sound pressure was 34.5 dB, and the difference from the case where no drip-proof member was provided was -5.6 dB.

  When a vinyl chloride resin thin plate having a thickness of 0.2 mm was provided, the peak value of the sound pressure was 31.3 dB, and the difference from the case where no drip-proof member was provided was -8.8 dB.

  When a styrene resin thin plate having a thickness of 0.3 mm was provided, the peak value of sound pressure was 32.8 dB, and the difference from the case where no drip-proof member was provided was −7.3 dB.

  When a vinyl chloride resin thin plate having a thickness of 0.5 mm was provided, the peak value of the sound pressure was 31.6 dB, and the difference from the case where no drip-proof member was provided was -8.5 dB.

  As can be seen from the comparison of the peak values of the sound pressure described above, when a mesh having a mesh size of 200 mesh is provided, the sound pressure level is slightly lowered compared to the case where a drip-proof member is not provided. Thus, the sound can be detected by the microphone 20.

  In addition, when a thin aluminum plate having a thickness of 0.05 mm is provided, sound can be detected by the microphone 20 at a sound pressure level substantially equal to that when a mesh having a mesh size of 200 mesh is provided. Moreover, the amount of decrease in the sound pressure level when a thin aluminum plate having a thickness of 0.05 mm is provided is smaller than that when a thin copper plate having a thickness of 0.01 mm is provided. . Since the aluminum thin plate having a thickness of 0.05 mm is thicker than the copper thin plate having a thickness of 0.01 mm, the aluminum thin plate is easy to handle and can be easily provided on the front surface of the porous plate-like structural member 40. .

  Thus, as the drip-proof member or the waterproof member provided on the front surface of the porous plate-like structural member 40, a mesh or a thin plate of various materials can be used. From the above results, the mesh size is particularly large. It can be seen that a 200 mesh mesh and a 0.05 mm thick aluminum sheet are preferred.

[Third Embodiment]
A monitoring device according to a third embodiment of the present invention will be described with reference to FIGS. FIG. 12 is a schematic diagram showing a configuration of the monitoring device according to the present embodiment, FIG. 13 is a schematic diagram showing a specific structure of the monitoring device according to the present embodiment, and FIG. 13 (b) is a side sectional view of the monitoring device 54. The same components as those of the monitoring device according to the first embodiment and the second embodiment and the abnormality monitoring system using the same are denoted by the same reference numerals, and description thereof is omitted or simplified.

  The monitoring device 54 according to the present embodiment is characterized in that the structure of the antenna unit is different from the monitoring device 10 according to the first embodiment and the second embodiment.

  In the first embodiment and the second embodiment, the radio wave reflector 30 is provided for each of the two pole antennas 28 that are the antennas of the radio device 26, and the space around the two pole antennas 28 is set. In the present embodiment, such a radio wave reflector is not provided, but the space around the two pole antennas 28 is not separated.

  As shown in FIG. 13 (a), one including two pole type antennas 28 is provided in the upper lid 18b that accommodates the two pole type antennas 28 without providing a metal wave reflector having a partial cylindrical shape. Form a space. The radio wave reflector 62 is provided at the bottom of the upper lid 18b. In the case of providing a metal radio wave reflector having a partial cylindrical shape, it is necessary to secure a distance from the pole type antenna, which is a limitation on downsizing of the monitoring device. In the third embodiment, however, The monitoring device can be reduced in size without being restricted.

  A radio wave incident on the explosion-proof enclosure 18 through the radio wave transmission / reception window 36 is reflected by a radio wave reflector 62 provided at the bottom of the upper lid 18b. The radio wave reflector 62 provided at the bottom of the upper lid 18b efficiently receives radio waves by the two pole antennas 28 functioning as diversity antennas, and prevents the influence of radio waves on the circuit inside the main body 18a.

  In addition, the monitoring device 54 according to the present embodiment uses the metal thin plate 60 as a porous plate-like structure as a drip-proof member for imparting drip-proof properties to the acoustic detection window 32 or a waterproof member for imparting waterproof properties. It is characterized in that it is provided on the rear surface of the material 40.

  As shown in FIGS. 12 and 13B, the acoustic detection window 32 in the monitoring device 54 according to the present embodiment is further provided with a metal thin plate 60 on the rear surface of the porous plate-like structural member 40.

  The metal thin plate 60 is a drip-proof member for imparting drip-proof properties to the sound detection window 32 or a waterproof member for imparting waterproof properties without hindering the propagation of sound into the explosion-proof explosion-proof housing 18. It is. The metal thin plate 60 is, for example, an aluminum thin plate having a thickness of about 0.05 mm. Since the propagation of sound into the explosion-proof enclosure 18 is not hindered by the metal thin plate 60, the sound in the monitored facility can be detected by the microphone 20 in the explosion-proof enclosure 18.

  The material of the metal thin plate 60 may be copper, stainless steel, titanium, or the like in addition to the aluminum thin plate. In addition to nickel, the material of the porous plate-like structural member 40 may be nickel-chromium alloy, stainless steel, cobalt alloy, titanium alloy, or the like.

  As described above, in the monitoring device 54 according to the present embodiment, the metal thin plate 60 is provided on the rear surface of the porous plate-like structural member 40, so that the acoustic detection window 32 has drip-proof or waterproof properties. Therefore, liquid such as moisture can be prevented from entering the explosion-proof enclosure 18 from the acoustic detection window 32. As a result, the monitoring device 54 according to the present embodiment can monitor the abnormality of the monitoring target equipment while protecting the device such as the microphone 20 in the explosion-proof enclosure 18 from the liquid such as moisture. According to the monitoring device 54 according to the present embodiment, for example, it is possible to monitor abnormality of a monitoring target facility that may cause liquid splash.

  In the monitoring device 54 according to the present embodiment, the metal thin plate 60 is provided on the rear surface of the porous plate-like structural member 40. Therefore, even if a spark occurs for some reason inside the monitoring device 54, the metal thin plate 60 is provided. Due to the fire resistance, the porous plate-like structural member 40 is protected and the acoustic detection window 32 is not destroyed. Thereby, even if a spark occurs for some reason inside the monitoring device 54, it does not spread outside the monitoring device 54, and a highly safe explosion-proof performance can be realized.

  In addition, as a drip-proof member for imparting drip-proof properties to the acoustic detection window 32 or a waterproof member for imparting waterproof properties, instead of the metal thin plate 60, a resin thin plate or a metal or resin-made member is used. You may provide a mesh so that the rear surface of the porous plate-shaped structure material 40 may be covered.

[Modified Embodiment]
The present invention is not limited to the above embodiment, and various modifications can be made.

  For example, in the above embodiment, the case where the acoustic detection window 32 is configured using the porous plate-shaped structural member 40 made of a metal porous body has been described as an example. However, the structural material configuring the acoustic detection window 32 is limited to this. Is not to be done. The structural material constituting the sound detection window 32 may be any material as long as it has air permeability and satisfies the explosion-proof specification so that the sound in the facility to be monitored can propagate into the explosion-proof housing 18. For example, the acoustic detection window 32 may be configured using an explosion-proof wire mesh having a laminated structure.

  Moreover, although the said embodiment demonstrated to the example the case where the image pick-up window 34 was comprised using the pressure | voltage resistant glass plate 44, the structural material which comprises the image pick-up window 34 is not limited to this. The structural material constituting the image capturing window 34 may be any material as long as it has visible light permeability and satisfies the explosion-proof specification.

  In the above-described embodiment, the case where the radio wave transmission / reception window 36 is configured using the pressure-resistant glass plate 52 has been described as an example, but the structural material configuring the radio wave transmission / reception window 36 is not limited thereto. The structural material constituting the radio wave transmission / reception window 36 may be any material as long as it has radio wave permeability and satisfies the explosion-proof specification.

  Moreover, although the said embodiment demonstrated the case where this invention was applied to abnormality monitoring, such as refineries, this invention is applied to abnormality monitoring of plants, such as a petrochemical plant other than a refinery, a factory, a power plant. You may apply.

DESCRIPTION OF SYMBOLS 10 ... Monitoring apparatus 12 ... Wireless head office 14 ... Wireless repeater 16 ... Monitoring processing apparatus 18 ... Explosion-proof enclosure 18a ... Main-body part 18b ... Upper cover part 18c ... Front wall part 20 ... Microphone 22 ... Camera 24 ... Information processor 26 ... Radio 27 ... Power supply unit 28 ... Pole antenna 30 ... Radio wave reflector 32 ... Acoustic detection window 34 ... Image capturing window 36 ... Radio wave transmission / reception window 38 ... Opening 40 ... Porous plate-like structure material 42 ... Opening 44 ... Pressure resistance Glass plate 46 ... Fixing jig 48 ... Fixing jig 50 ... Opening 52 ... Pressure-resistant glass plate 54 ... Monitoring device 56 ... Mesh 60 ... Metal thin plate 62 ... Radio wave reflector

Claims (6)

A housing having a flameproof structure,
A microphone built in the housing for detecting sound in the monitored facility;
A camera built in the housing for capturing an image in the monitored facility;
An information processor built in the housing, processing acoustic data from the microphone and image data from the camera, and controlling the microphone and the camera;
A radio for transmitting the acoustic data and the image data processed by the information processor and receiving control signals of the microphone and the camera;
A monitoring device having an antenna built in the housing and connected to the radio ,
The housing includes a radio wave transmission / reception window having radio wave permeability, and a portion provided with the radio wave transmission / reception window is formed to be inclined downward to the side of the monitoring device,
The monitoring device , wherein the antenna transmits and receives radio waves through the radio wave transmission / reception window . The monitoring device according to claim 1,
The housing has an acoustic detection window constituted by a breathable structure material having breathability,
The said microphone detects the sound in the said monitoring object installation through the said sound detection window. The monitoring apparatus characterized by the above-mentioned. The monitoring device according to claim 2, wherein
The breathable structural member is made of a metal porous body. The monitoring device according to claim 2 or 3,
It is provided on the front surface or the rear surface of the breathable structure material, and further includes a mesh for imparting waterproofness to the acoustic detection window or a thin plate for imparting dustproof and waterproof properties to the acoustic detection window. Monitoring device. The monitoring device according to any one of claims 1 to 4 ,
A monitoring apparatus, further comprising: a radio wave reflector that is provided in the housing, reflects radio waves incident on the housing through the radio wave transmission / reception window, and reflects radio waves radiated from the antenna. The monitoring device according to claim 5 , wherein
The antenna is a pole type antenna,
The radio wave reflector has a partial cylindrical shape, and is provided with its open side facing the radio wave transmission / reception window so as to surround the antenna along the antenna.

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