CN217506142U - Protection device of long-term micro-seismic monitoring equipment - Google Patents
Protection device of long-term micro-seismic monitoring equipment Download PDFInfo
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- CN217506142U CN217506142U CN202221536511.1U CN202221536511U CN217506142U CN 217506142 U CN217506142 U CN 217506142U CN 202221536511 U CN202221536511 U CN 202221536511U CN 217506142 U CN217506142 U CN 217506142U
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- 239000002184 metal Substances 0.000 claims abstract description 60
- 230000005540 biological transmission Effects 0.000 claims abstract description 22
- 238000005192 partition Methods 0.000 claims description 12
- 238000007789 sealing Methods 0.000 claims description 7
- 238000012806 monitoring device Methods 0.000 claims description 6
- 230000000149 penetrating effect Effects 0.000 claims description 5
- 238000007493 shaping process Methods 0.000 claims description 2
- 239000012720 thermal barrier coating Substances 0.000 claims 1
- 230000000694 effects Effects 0.000 abstract description 9
- 238000009434 installation Methods 0.000 abstract description 8
- 230000007613 environmental effect Effects 0.000 abstract description 5
- 230000001681 protective effect Effects 0.000 abstract 1
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- 238000005516 engineering process Methods 0.000 description 5
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- 239000011435 rock Substances 0.000 description 3
- 230000035939 shock Effects 0.000 description 3
- 239000011083 cement mortar Substances 0.000 description 2
- 238000009413 insulation Methods 0.000 description 2
- 238000004519 manufacturing process Methods 0.000 description 2
- 238000009825 accumulation Methods 0.000 description 1
- 238000004873 anchoring Methods 0.000 description 1
- 239000003245 coal Substances 0.000 description 1
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- 238000010586 diagram Methods 0.000 description 1
- 239000000428 dust Substances 0.000 description 1
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- 239000003079 shale oil Substances 0.000 description 1
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Abstract
The utility model relates to a long-term protection device of micro-seismic monitoring equipment, it includes the cabinet body and fixed subassembly, the internal holding cavity that has an installation electronic equipment of cabinet, fixed subassembly includes cement base and a plurality of metal bar, the cement base is poured and is formed under the ground, and a plurality of one end of metal bar all anchors in the cement base, and a plurality of the other end of metal bar all extends to set up on the cement base and via a support piece with cabinet body fixed connection, the cement base is worn to be equipped with and is fixed with a PE pipe along vertical direction, PE pipe one end is higher than the cement base setting, and the other end extends to the underground for the installation wave detector, and draws forth the transmission line; the problem of protection device protective measures among the prior art are limited, receive the influence of artificial or environmental factor easily, the protection effect is poor is solved.
Description
Technical Field
The utility model relates to an earthquake monitoring technology field especially relates to a long-term protection device of little earthquake monitoring facilities.
Background
The microseism monitoring technology is originated from the physical phenomenon of acoustic emission of loaded rocks, and is developed into a novel high-tech monitoring technology. The micro-seismic monitoring technology is a geophysical technology for monitoring the influence, effect and underground state of the micro-seismic events generated in production activities by observing and analyzing the micro-seismic events, is widely applied to fracture monitoring of unconventional oil and gas reservoirs such as shale oil and gas, coal bed gas, hot dry rock and the like at present, and is also applied to deformation monitoring of mines, dams and rocks.
Common microseismic observation modes include in-well monitoring, ground large-array survey line monitoring and ground station monitoring. The monitoring in the well is usually arranged and received in one or more wells adjacent to the monitoring fracturing well, the signal-to-noise ratio of monitoring data in the well is high, the depth precision is high, the positioning can be realized in real time, the requirement on site conditions is high, more than two monitoring wells are needed to ensure the positioning precision when the monitoring distance is far away, the monitoring cost is high, and the long-term monitoring cannot be realized. The ground large-array measuring line monitoring is characterized in that a plurality of radial measuring lines are distributed by taking a fracturing well as a center, a conventional single-component geophone is generally adopted by the geophone, the track distance is 10-40m, the total number of monitoring tracks is not less than 1000, the monitoring mode is large in coverage area and high in horizontal positioning accuracy, but the cost is high, and the geophone is generally used for temporary monitoring during fracturing. The ground station monitoring system generally comprises a series of independent stations according to a certain grid form, and the ground stations have the advantages of flexible observation mode, high horizontal direction positioning accuracy, low monitoring cost and the like, can perform long-term monitoring, and have wider application field.
Because the equipment monitored by the ground station needs to work in various field environments for a long time, in order to prolong the service life of acquisition equipment and improve the stability of the equipment, a special protection device is adopted in the prior art to protect the station detection equipment, for example, the Chinese utility model patent with the patent application number of CN202023199513.X provides a protection device of micro-earthquake detection equipment, which comprises an upper half body and a lower half body, wherein the upper half body and the lower half body are buckled together to form an integral structure, and the upper half body and the lower half body are of a composite structure consisting of a metal shell, a heat insulation material, an inner shell, a shock pad and an inner container from outside to inside; the shock pad is arranged between the inner shell and the inner container in the prior art, the shock protection equipment capable of absorbing external transmitted vibration is limited in protection effect and only capable of reducing vibration, the device is limited in protection measures, and the device is easy to be influenced by human or environmental factors in long-term field use, so that the device is moved or overturned, and the service life of the earthquake monitoring station is influenced.
Therefore, the protection device in the prior art has the defects of limited protection measures, easy influence of human or environmental factors and poor protection effect.
SUMMERY OF THE UTILITY MODEL
In view of the above, there is a need to provide a protection device for a long-term micro-seismic monitoring device, so as to solve the problems that the protection device in the prior art has limited protection measures, is easily affected by human or environmental factors, and has a poor protection effect.
The utility model provides a long-term protection device of micro-seismic monitoring equipment includes the cabinet body and fixed subassembly, the internal holding cavity that has an installation electronic equipment of cabinet, fixed subassembly includes cement base and a plurality of metal rod, cement base pours the shaping under ground, and is a plurality of the one end of metal rod all anchor in the cement base, it is a plurality of the other end of metal rod all extends to set up on the cement base and via a support piece with cabinet body fixed connection, the cement base wears to be equipped with along vertical direction and is fixed with a PE pipe, PE pipe one end is higher than the cement base sets up, and the other end extends to the underground for install the wave detector, and draw forth the transmission line.
Further, a cabinet door is hinged to the cabinet body, a lock is fixedly arranged on the cabinet door and used for opening and closing the cabinet door, sealing rubber strips are fixedly arranged at the edge positions of the inner side face of the cabinet door, and the outer side face of the cabinet door is an identification area.
Further, the internal portion of cabinet is provided with a plurality of division boards along vertical direction range, a plurality of draw-in grooves have all been seted up on the internal relative both sides wall of cabinet, arbitrary one the both ends face of division board is inserted respectively and is located two of the same height of the internal both sides wall of cabinet in the draw-in groove, be used for with the holding cavity sets up by layers, the division board with the cabinet body for leave the clearance between the inner wall of cabinet door, the line hole of walking that supplies the transmission line to pass is seted up to cabinet body bottom.
Furthermore, the partition board is provided with three, and will the holding cavity divide into four layers and sets up, different electronic equipment is installed to the three-layer on the cabinet body, the bottom of the cabinet body is vacant to be set up.
Further, the cabinet body for one side of cabinet door is provided with and is used for installing solar panel A-frame, the A-frame with the top fixed connection of the cabinet body, the line hole has been seted up to one side that the A-frame was installed to the cabinet body.
Further, a temperature and humidity detector is fixedly arranged on the inner wall of the cabinet body.
Further, the surface of the cabinet body is coated with a waterproof heat-insulating coating.
Furthermore, the support piece is arranged on the cement base along the vertical direction, the metal rods are anchored in the cement base through two oppositely arranged metal sheets, the metal rods are fixedly arranged on the two metal sheets in a penetrating manner, the metal sheets are poured in the cement base, and a circular cavity is formed in the middle of each metal sheet and used for allowing the PE pipe to penetrate through.
Furthermore, support piece sets up along vertical direction on the cement base, support piece's lower extreme with metal bar fixed connection, the upper portion of metal bar with cabinet body bottom surface fixed connection is used for with the cabinet body is fixed in the position that is higher than ground.
Furthermore, the support piece comprises a support tube and two support pieces, the support tube is arranged in a hollow mode, the upper end of the PE tube extends into the support tube, a rubber cover is fixed at the upper end of the PE tube in a sealing mode, a transmission line penetrates through the rubber cover, the two support pieces are respectively fixedly arranged at two ends of the support tube, and the joints of the two support pieces and the support tube are both provided with openings.
Compared with the prior art, the protection device of the long-term micro-earthquake monitoring equipment provided by the utility model firmly fixes the cabinet body on the ground through the arrangement of the fixing component, so that the cabinet body is not easily influenced by human damage and external factors; specifically, the fixing component comprises a cement base and a plurality of metal rods, the cement base is poured and formed under the ground so as to be fixedly connected with the ground, one end of each metal rod is anchored in the cement base, the other end of each metal rod extends to the cement base and is fixedly connected with the cabinet body, the cabinet body is firmly fixed on the cement base through the metal rods, the cabinet body is stably fixed on the ground through the arrangement of the metal rods and the cement base, the cabinet body is not easily influenced by human factors and external factors, the cabinet body is prevented from moving or overturning, meanwhile, a PE pipe is fixedly arranged in the cement base in a penetrating mode, one end of the PE pipe is higher than the cement base, the other end of the PE pipe extends to the underground to install a detector, a hollow structure in the PE pipe is used for leading out a transmission line on the detector, a stable routing channel is provided by the PE pipe which is relatively fixed, and the transmission line is protected, the earthquake monitoring device is prevented from being damaged, so that the earthquake monitoring device is protected from being used for long-term operation in the field.
Drawings
Fig. 1 is a schematic structural diagram of an entire embodiment of a protection device for a long-term micro-seismic monitoring device according to the present invention;
fig. 2 is a schematic view of the overall structure of the cabinet body in the embodiment of the protection device for long-term micro-earthquake monitoring equipment provided by the present invention;
fig. 3 is a schematic view of a connection structure of a metal rod and a metal sheet in the embodiment of the protection device for long-term microseism monitoring equipment provided by the present invention;
fig. 4 is the utility model provides a protection device of long-term micro-seismic monitoring equipment the layering sketch map of the internal portion of cabinet in this embodiment.
In the figure: 1. a cabinet body; 2. a fixing component; 3. a PE pipe; 11. an accommodating cavity; 12. a cabinet door; 121. a lock; 122. sealing rubber strips; 13. a partition plate; 14. a card slot; 15. a wiring hole; 16; a triangular bracket; 17. a wire passing hole; 18. a temperature and humidity detector; 19. a threading hole; 21. a cement base; 22. a metal rod; 23. a support member; 24. a metal sheet; 231. supporting a pipe; 232. a support sheet; 31. and a rubber cover.
Detailed Description
The following detailed description of the preferred embodiments of the invention, which is to be read in connection with the accompanying drawings, forms a part of this application, and together with the embodiments of the invention, serve to explain the principles of the invention and not to limit its scope.
As shown in fig. 1-2, the protection device of a long-term micro-seismic monitoring device in this embodiment includes a cabinet body 1 and a fixed component 2, a containing cavity 11 for installing electronic equipment is provided in the cabinet body 1, the fixed component 2 includes a cement base 21 and a plurality of metal rods 22, the cement base 21 is poured and formed under the ground, one ends of the plurality of metal rods 22 are anchored in the cement base 21, the other ends of the plurality of metal rods 22 are extended to the cement base 21 and are provided, and are fixedly connected with the cabinet body 1 via a supporting piece 23, the cement base 21 is provided with a PE tube 3 along the vertical direction in a penetrating manner, one end of the PE tube 3 is higher than the cement base 21, and the other end is extended to the ground for installing a detector and leading out a transmission line.
The cabinet body 1 is a main body of the protection device, and various electronic devices for earthquake monitoring are arranged in the cabinet body 1; the fixing component 2 is a fixing structure for stably fixing the cabinet body 1 on the ground, and comprises an anchoring piece and a cement base 21, when the protection device is installed, firstly a cement base 21 pit is dug on the ground, then a plurality of metal rods 22 are penetrated in the pit along the vertical direction, cement is poured, the upper ends of the metal rods 22 penetrate through the cement base 21 and are fixedly connected with the cabinet body 1 through a supporting piece 23, due to the arrangement of the metal rods 22 and the cement base 21, the cabinet body 1 is stably fixed on the bottom surface and cannot easily move or overturn due to the influence of external factors, meanwhile, a PE pipe 3 is penetrated in the cement base 21, one end of the PE pipe 3 is higher than the cement base 21, the other end of the PE pipe 3 extends to the ground for installing a detector and leading out a transmission line, a stable routing channel is provided by utilizing the relatively fixed PE pipe 3 to provide protection for the transmission line and avoid the transmission line from being damaged, therefore, the protection of the earthquake monitoring equipment is enhanced, and the earthquake monitoring equipment can be used for long-term detection.
The PE pipe 3 and the detector are buried in the ground before the cement mortar 21 is poured, and the PE pipe 3 is also poured into the cement mortar 21 at the time of pouring.
The counter in this embodiment provides the structure of protection for electronic equipment, as shown in fig. 2, multiple electronic equipment installs in it, therefore it needs to possess good guard effect to realize carrying out long-term effectual protection to seismic monitoring equipment in the field, the structure should set up rationally simultaneously, so that the workman installs.
In order to facilitate the installation of the electronic device in the cabinet body 1, the electronic device in the cabinet body 1 is not reliably protected, in a preferred embodiment, a cabinet door 12 is hinged to the cabinet body 1, a lock 121 is fixedly arranged on the cabinet door 12 for opening and closing the cabinet door 12, a sealing rubber strip 122 is fixedly arranged at the edge position of the inner side surface of the cabinet door 12, and the outer side surface of the cabinet door 12 is an identification area.
Wherein, cabinet door 12 can open and close the setting for be convenient for the electronic equipment of dismouting earthquake monitoring usefulness, the setting of tool to lock 121 is avoided irrelevant personnel to open the cabinet body 1 at will, causes destruction to the electronic equipment in the cabinet body 1, and the waterproof and heat-proof properties of the cabinet body 1 can further be strengthened in setting up of joint strip 122, and the mark district can be printed affiliated unit, content such as warning poster, be used for warning irrelevant personnel and do not close to, and the while causes the harm to earthquake monitoring equipment.
In order to reasonably plan the space in the cabinet body 1, in a preferred embodiment, a plurality of partition plates 13 are arranged in the cabinet body 1 along the vertical direction, a plurality of clamping grooves 14 are respectively formed in two opposite side walls in the cabinet body 1, two end faces of any partition plate 13 are respectively inserted into the two clamping grooves 14 at the same height of the two side walls in the cabinet body 1, so as to arrange the accommodating cavities 11 in a layered manner, a gap is reserved between the partition plate 13 and the inner wall of the cabinet body 1 relative to the cabinet door 12, and a wiring hole 15 for a transmission line to pass through is formed in the bottom of the cabinet body 1.
It can be understood that the number and the installation position of the partition plates 13 can be adjusted according to actual use requirements, so that the number of layers and the height of each layer of the accommodating cavity 11 in the cabinet body 1 are adjusted to adapt to installation of different devices, a gap reserved between the partition plates 13 and the inner wall of the cabinet body 1 can be used for electronic devices on different interlayers to be connected with wires, and the wire-passing hole 15 is formed in the bottom of the cabinet body 1 and used for facilitating a transmission line of a detector to pass through the bottom of the cabinet body 1 and be connected with the electronic devices in the cabinet body 1.
In a preferred embodiment, as shown in fig. 4, three partition plates 13 are provided, and the accommodating cavity 11 is divided into four layers, wherein different electronic devices are installed on the upper three layers of the cabinet 1, and the bottom layer of the cabinet 1 is vacant.
Wherein, can divide into four layers setting with holding cavity 11, first layer mountable radio signal intensifier from top to bottom, inside inserts 4G thing networking card, the transmission of mainly used acquisition signal, threaded hole 19 has been seted up on the cabinet body 1 lateral wall that corresponds for connect signal transmission and receiving circuit, the little earthquake of second floor installation gathers the host computer, it is the core equipment of whole little earthquake monitoring to gather the host computer, third layer installation electrical power generating system, fourth floor space is minimum, be used for separating equipment and cabinet body 1 bottom surface, need not to place any equipment.
In order to improve the cruising ability of the earthquake monitoring equipment, in a preferred embodiment, as shown in fig. 1, a triangular bracket 16 for mounting a solar panel is arranged on one side of the cabinet body 1 opposite to the cabinet door 12, the triangular bracket 16 is fixedly connected with the top of the cabinet body 1, and a wire passing hole 17 is formed in one side of the cabinet body 1 on which the triangular bracket 16 is mounted.
The triangular support 16 can be provided with a solar cell panel for transmitting electric energy to the cabinet body 1, so that the cruising ability of the earthquake monitoring equipment is improved, the earthquake monitoring equipment can still run for a long time in a place lacking current transmission in the field, and the wire passing hole 17 is arranged for transmitting the electric energy generated by solar energy to the electronic equipment in the cabinet body 1 through the wire passing hole 17 via a wire.
In order to ensure that the working environment of the electronic equipment in the cabinet 1 is appropriate, in a preferred embodiment, a temperature and humidity detector 18 is fixedly arranged on the inner wall of the cabinet 1.
Wherein, temperature and humidity detector 18 can detect the temperature and the humidity condition of cabinet 1 internal environment, if discover temperature and humidity anomaly can in time maintain to guarantee that the electronic equipment in the cabinet 1 can be in the field normal operating for a long time.
In order to reduce the influence of environmental factors on the internal environment of the cabinet 1, in a preferred embodiment, the cabinet 1 is coated with a waterproof thermal insulation coating on the surface.
Wherein, the waterproof heat insulation coating can avoid entering the cabinet body 1 in the rainy day to cause damage, and can also reduce the influence of ambient temperature to the cabinet body 1.
In this embodiment, the effect of fixed subassembly 2 has mainly made cabinet body 1 stably fixed subaerial, has certain destruction resistance, can avoid most external factors to cause the influence to the fixed state of cabinet body 1.
In order to ensure the stability of the connection between the cabinet 1 and the cement base 21, in a preferred embodiment, as shown in fig. 3, the metal rods 22 are anchored in the cement base 21 through two oppositely disposed metal sheets 24, the metal rods 22 are all fixed on the two metal sheets 24 in a penetrating manner, the metal sheets 24 are poured in the cement base 21, and a circular hollow space is formed in the middle of the metal sheets 24 for the PE pipe 3 to pass through.
Wherein, sheetmetal 24 is the square structure of level setting, metal bar 22 is provided with four, locate 24 four corners of sheetmetal respectively, and the upper end is provided with the screw thread, two 24 sheetmetals via 22 relatively fixed settings of metal bar, anchor assembly when pouring in cement base 21, because the sheetmetal 24 of level setting and the metal bar 22's of vertical setting anchor effect, make anchor assembly stable fixed between whole and the cement base 21, difficult production is rocked, thereby make and also can keep relatively stable position relation with between the cement base 21 with the cabinet body 1 of metal bar 22 fixed connection.
In order to avoid the earthquake monitoring equipment from being soaked by water flow on the ground, in a preferred embodiment, as shown in fig. 1, a support 23 is vertically arranged on a cement base 21, the lower end of the support 23 is fixedly connected with a metal rod 22, and the upper part of the metal rod 22 is fixedly connected with the bottom surface of the cabinet 1, so as to fix the cabinet 1 at a position higher than the ground.
It will be appreciated that there may often be water accumulation on the floor in the field due to rain and the like, and in order to avoid the seismic monitoring equipment being immersed in water, the cabinet 1 may be mounted at a higher level than the floor by means of the support 23.
In order to make the supporting member 23 stably form the cabinet 1, in a preferred embodiment, the supporting member 23 includes a supporting tube 231 and two supporting pieces 232, the supporting tube 231 is disposed in a hollow manner, the upper end of the PE tube 3 extends into the supporting tube 231, the rubber cover 31 is fixed to the upper end of the PE tube 3 in a sealing manner, the transmission line passes through the rubber cover 31, the two supporting pieces 232 are respectively fixed to two ends of the supporting tube 231, and joints between the two supporting pieces 232 and the supporting tube 231 are both open.
Wherein, go up the stay 232 via bolt and 1 bottom fixed connection of cabinet body, metal rod 22 passes lower stay 232, and fix lower stay 232 on the cement base via the nut, it is directional structure with lower stay 232 to go up stay 232, with the increase area of contact, promote bearing capacity, avoid rocking at will, stay tube 231 is hollow structure, it sets up with walking line hole 15 coaxial line, the upper end of PE pipe 3 extends to in the stay tube 231, stay tube 231 can separate PE pipe 3 with the external world, be used for protecting the transmission line in the PE pipe 3, the sealed fixed rubber lid 31 of PE pipe 3 upper end can further prevent that dust and water from falling into in PE pipe 3.
The device is integrally made of a metal structure, has the advantages of high strength, firmness, durability, low cost and good safety performance, and is suitable for being used as a protection device for field long-term microseism monitoring.
Compared with the prior art: the utility model provides a protection device of long-term micro-earthquake monitoring equipment, which firmly fixes a cabinet body 1 on the ground through the arrangement of a fixing component 2, so that the cabinet body is not easily influenced by artificial damage and external factors; specifically, the fixing component 2 includes a cement base 21 and a plurality of metal rods 22, the cement base 21 is poured and formed under the ground so as to be fixedly connected with the ground, one end of each metal rod 22 is anchored in the cement base 21, and the other end of each metal rod 22 extends to the cement base 21 and is fixedly connected with the cabinet body 1, so that the cabinet body 1 is firmly fixed on the cement base 21 through the metal rods 22, the cabinet body 1 is stably fixed on the ground through the arrangement of the metal rods 22 and the cement base 21, so that the cabinet body 1 is not easily affected by human factors and external factors, and is prevented from moving or overturning, meanwhile, the PE pipe 3 is fixedly inserted into the cement base 21, one end of the PE pipe is higher than the cement base 21, the other end of the PE pipe extends to the ground so as to install the detector, a transmission line on the detector is led out through a hollow structure in the PE pipe 3, a stable routing channel is provided by using the relatively fixed PE pipe 3, the protection is provided for the transmission line, the transmission line is prevented from being damaged, and the long-term operation and use of the earthquake monitoring equipment in the field are protected.
The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention should be covered by the present invention.
Claims (10)
1. A protection device of long-term micro-seismic monitoring equipment is characterized by comprising a cabinet body and a fixing assembly;
the cabinet body is internally provided with an accommodating cavity for mounting electronic equipment;
the fixed subassembly includes cement base and a plurality of metal rod, the cement base is pour the shaping under ground, and is a plurality of the one end of metal rod all anchor in the cement base, it is a plurality of the other end of metal rod all extends to set up on the cement base and via a support piece with cabinet body fixed connection, the cement base is worn to be equipped with along vertical direction and is fixed with a PE pipe, PE pipe one end is higher than the cement base sets up, and the other end extends to the underground for install the wave detector, and draw forth the transmission line.
2. The protection device for the long-term micro-seismic monitoring equipment according to claim 1, wherein a cabinet door is hinged to the cabinet body, a lock is fixedly arranged on the cabinet door and used for opening and closing the cabinet door, a sealing rubber strip is fixedly arranged at an edge position of the inner side surface of the cabinet door, and the outer side surface of the cabinet door is a mark area.
3. The long-term microseism monitoring equipment protection device according to claim 2, wherein a plurality of partition plates are vertically arranged inside the cabinet body, a plurality of slots are formed in two opposite side walls of the cabinet body, two end faces of any one partition plate are respectively inserted into two slots at the same height of the two side walls of the cabinet body so as to layer the accommodating cavities, a gap is formed between the partition plate and the inner wall of the cabinet body opposite to the cabinet door, and a wiring hole for a transmission line to pass through is formed in the bottom of the cabinet body.
4. The protection device for the long-term micro-seismic monitoring equipment according to claim 3, wherein the number of the partition plates is three, the accommodating cavity is divided into four layers, different electronic equipment is mounted on the upper three layers of the cabinet body, and the bottom layer of the cabinet body is arranged in a vacant mode.
5. The protection device for the long-term micro-seismic monitoring equipment according to claim 2, wherein a triangular bracket for mounting a solar panel is arranged on one side of the cabinet body opposite to the cabinet door, the triangular bracket is fixedly connected with the top of the cabinet body, and a wire passing hole is formed in one side of the cabinet body on which the triangular bracket is mounted.
6. The protection device for the long-term microseism monitoring equipment according to claim 1, wherein a temperature and humidity detector is fixedly arranged on the inner wall of the cabinet body.
7. The long-term microseismic monitoring device protection apparatus of claim 1 wherein the cabinet surface is coated with a waterproof thermal barrier coating.
8. The protection device for long-term microseismic monitoring equipment as claimed in any one of claims 1-7 wherein a plurality of metal rods are anchored in the cement base by two oppositely disposed metal sheets, each metal rod is fixed on the two metal sheets by penetrating, the metal sheets are poured in the cement base, and a circular hollow is formed in the middle of the metal sheets for PE pipe to pass through.
9. The protection device for long-term microseismic monitoring equipment as claimed in claim 8, wherein the support member is vertically arranged on the cement base, the lower end of the support member is fixedly connected with the metal rod, and the upper part of the metal rod is fixedly connected with the bottom surface of the cabinet body, so as to fix the cabinet body at a position higher than the ground.
10. The protection device for long-term micro-seismic monitoring equipment according to claim 9, wherein the support member comprises a support tube and two support pieces, the support tube is hollow, the upper end of the PE tube extends into the support tube, a rubber cover is fixed on the upper end of the PE tube in a sealing manner, the transmission line passes through the rubber cover, the two support pieces are respectively fixed on two ends of the support tube, and the joints between the two support pieces and the support tube are both open.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202221536511.1U CN217506142U (en) | 2022-06-17 | 2022-06-17 | Protection device of long-term micro-seismic monitoring equipment |
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CN202221536511.1U CN217506142U (en) | 2022-06-17 | 2022-06-17 | Protection device of long-term micro-seismic monitoring equipment |
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CN202221536511.1U Expired - Fee Related CN217506142U (en) | 2022-06-17 | 2022-06-17 | Protection device of long-term micro-seismic monitoring equipment |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN116449414A (en) * | 2023-03-07 | 2023-07-18 | 中电环宇(北京)建设工程有限公司 | Microseismic monitoring device of semiconductor equipment manufacturing factory building |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN116449414A (en) * | 2023-03-07 | 2023-07-18 | 中电环宇(北京)建设工程有限公司 | Microseismic monitoring device of semiconductor equipment manufacturing factory building |
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