CN221301031U - Natural gas pipeline pressure detection control device based on 5G - Google Patents

Abstract

The utility model discloses a natural gas pipeline pressure detection control device based on 5G, which comprises a pipeline main body, a 5G detector and a fixed plate, wherein the 5G detector is arranged on a flange coil pipe at the top of the pipeline main body, and the fixed plate is nailed on the ground below the pipeline main body. According to the utility model, two arc plates are attached to the pipeline main body during assembly, one sides of the two arc plates are attached to each other, the protective shells are spliced to cover the 5G detector inside, then the fixing plate is installed at a proper position, the locating sleeve on the screw A is rotated to enable the locating sleeve to move upwards, a part of the locating sleeve is sleeved on the screw B, the screw B and the screw A are in threaded connection with the locating sleeve together to complete fixation, and the inserted rod is inserted into a round hole at the top of the locating sleeve, so that the locating sleeve cannot rotate, and then the splicing between the protective shells is very firm and stable, so that the 5G detector can be effectively protected from dust, and the problem that the locating sleeve is exposed to the outside and is easily damaged is avoided.

Description

Natural gas pipeline pressure detection control device based on 5G

Technical Field

The utility model relates to the technical field of natural gas pipeline pressure detection, in particular to a natural gas pipeline pressure detection control device based on 5G.

Background

When the existing natural gas is conveyed through the conveying pipeline, a pressure detection device is arranged on the conveying pipeline to measure the pressure of the pipeline, whether the pipeline is sealed or not is detected in real time, along with the development of technology, the existing pressure detection equipment is also provided with a 5G communication module, and pressure data are transmitted to a cloud server or a local monitoring center in real time by utilizing the characteristics of high speed and low delay of 5G, so that the efficiency of data transmission is improved.

The applicant searches that the existing pressure detection devices are all directly installed on a pipeline, for example, a pressure detection device for a natural gas pipeline disclosed in patent number CN216349324U is directly installed on the top of the pipeline, however, because of no good protection structure, dust is easily accumulated on the surface of the device during long-time use, heat dissipation is affected, corrosion of parts is caused, and service life is reduced.

The applicant therefore proposes a 5G-based natural gas pipeline pressure detection control device to address this issue.

Disclosure of utility model

The utility model provides a 5G-based natural gas pipeline pressure detection control device, which solves the problems that the existing detection device is directly arranged at the top of a pipeline, dust is easy to accumulate on the surface of the device when the device is used for a long time, heat dissipation is affected, corrosion of parts is caused, and the service life is reduced because the existing detection device has no good protection structure.

In order to solve the technical problems, the natural gas pipeline pressure detection control device based on 5G comprises a pipeline main body, 5G detectors and a fixing plate, wherein the 5G detectors are installed on flange coils at the top of the pipeline main body, the fixing plate is nailed on the ground below the pipeline main body, arc plates are installed on two sides of the pipeline main body, protective shells are fixed at the tops of the two arc plates, the protective shells are mutually spliced to cover the 5G detectors inside, an assembly component is installed between the arc plates and the fixing plate, the assembly component comprises a screw A welded on the top surface of the fixing plate, a screw B is arranged above the screw A, the screw B and the screw A are in threaded connection with a locating sleeve in a common mode, and the screw B is welded at the bottom of the arc plates.

Further, the part that screw rod B upper end does not have the screw thread is fixed with the annular cover, screw rod B is in annular cover top sliding connection, annular cover bottom evenly is fixed with four inserted bars, the inserted bar passes the annular plate and inserts the round hole at locating sleeve top, and annular cover is fixed with the spring of cover outside the inserted bar with the annular plate, annular cover top surface and annular plate bottom surface laminating.

Furthermore, the top of the 5G detector is provided with an instrument panel through a connecting rod, the butt joint surfaces of the two protective shells are provided with arc-shaped notches corresponding to the flange coil pipe and the instrument panel connecting rod, and the butt joint surfaces of the two protective shells are adhered with elastic compression pads.

Furthermore, the top surfaces of the two protective shells are respectively fixed with an arc-shaped plate, the two arc-shaped plates are provided with corresponding external threads and are spliced together, the two arc-shaped plates enclose the instrument panel inside, and the two arc-shaped plates are connected with a transparent cylinder in a threaded mode.

Furthermore, the side wall of the protective shell is provided with an opening, and the shutter plate is nailed at the position outside the opening of the protective shell.

Further, a heat dissipation fan is installed on the inner wall of the protective shell, a temperature sensor is installed on the inner bottom surface of the protective shell, and the temperature sensor is in telecommunication connection with the heat dissipation fan.

Further, the front sides of the two protective shells are respectively provided with a buzzer and an alarm flashing lamp, the buzzer and the alarm flashing lamps are electrically connected with the 5G detector, and wiring of the buzzer and the alarm flashing lamps as well as the 5G detector penetrates through gaps of the butt joint surfaces of the two protective shells.

Compared with the related art, the 5G-based natural gas pipeline pressure detection control device provided by the utility model has the following beneficial effects:

according to the utility model, two arc plates are attached to the pipeline main body during assembly, one sides of the two arc plates are attached to each other, the protective shells are spliced to cover the 5G detector inside, then the fixing plate is installed at a proper position, the locating sleeve on the screw A is rotated to enable the locating sleeve to move upwards, a part of the locating sleeve is sleeved on the screw B, the screw B and the screw A are in threaded connection with the locating sleeve together to complete fixation, and the inserted rod is inserted into a round hole at the top of the locating sleeve, so that the locating sleeve cannot rotate, and then the splicing between the protective shells is very firm and stable, so that the 5G detector can be effectively protected from dust, and the problem that the locating sleeve is exposed to the outside and is easily damaged is avoided.

Drawings

FIG. 1 is a schematic overall perspective view of the present utility model;

FIG. 2 is a schematic diagram of the overall front internal structure of the present utility model;

FIG. 3 is a schematic elevational view of the mounting assembly of the present utility model;

fig. 4 is a schematic perspective view of the assembly component of the present utility model.

Reference numerals in the drawings: 1. a pipe body; 11. a flange coil; 2. a 5G detector; 21. a dashboard; 3. an arc plate; 4. a protective housing; 41. an elastic compression pad; 42. an arc-shaped plate; 43. a transparent cylinder; 44. a louver board; 45. a heat dissipation fan; 46. a temperature sensor; 47. a buzzer; 48. an alarm flashing lamp; 5. assembling the assembly; 51. a screw A; 52. a screw B; 53. a positioning sleeve; 54. a ring plate; 55. an annular sleeve; 56. a rod; 57. a spring; 6. and a fixing plate.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model; all other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

1-4, The utility model comprises a pipeline main body 1, A5G detector 2 and a fixed plate 6,5G, wherein the detector 2 is arranged on a flange coil 11 at the top of the pipeline main body 1, a fixed plate 6 is nailed on the ground below the pipeline main body 1, two sides of the pipeline main body 1 are provided with arc plates 3, the tops of the two arc plates 3 are fixedly provided with protective shells 4, the protective shells 4 splice each other to cover the 5G detector 2 inside, an assembly component 5 is arranged between the arc plates 3 and the fixed plate 6, the assembly component 5 comprises a screw A51 welded on the top surface of the fixed plate 6, a screw B52 is arranged above the screw A51, the screw B52 and the screw A51 are in threaded connection with a positioning sleeve 53 together, and the screw B52 is welded at the bottom of the arc plates 3;

the part of the upper end of the screw rod B52, which is not threaded, is fixed with a ring plate 54, the screw rod B52 is slidably connected with an annular sleeve 55 above the ring plate 54, four inserting rods 56 are uniformly fixed at the bottom of the annular sleeve 55, the inserting rods 56 penetrate through the ring plate 54 and are inserted into round holes at the top of the positioning sleeve 53, the annular sleeve 55 and the ring plate 54 are fixedly provided with springs 57 sleeved outside the inserting rods 56, and the top surface of the annular sleeve 55 is attached to the bottom surface of the ring plate 54.

The protection assembly comprises a design assembly component 5, a protection shell 4 and an arc plate 3, wherein when the protection assembly is carried out, the arc plate 3 at two positions is attached to a pipeline main body 1, one side of the arc plate 3 at two positions is attached to each other, the protection shell 4 is mutually spliced to cover A5G detector 2 inside, then a fixing plate 6 is installed at a proper position, a locating sleeve 53 on a screw A51 is rotated to enable the locating sleeve 53 to move upwards, a part of the locating sleeve 53 is sleeved on a screw B52, the screw B52 and the screw A51 are connected with the locating sleeve 53 in a threaded mode in common, meanwhile, before the locating sleeve 53 is rotated, an annular sleeve 55 is pulled upwards, the annular sleeve 55 is loosened when the locating sleeve 53 is rotated to the top end of the annular sleeve 53 to be attached to the bottom surface of a ring plate 54, the inserted rod 56 is reset to be inserted into a round hole at the top of the locating sleeve 53 under the action of a spring 57, the locating sleeve 53 cannot rotate, and then the locating sleeve 4 is spliced very firmly and stably, so that the locating sleeve 2 can be effectively protected, and the problem that the dust is exposed to be easily damaged is avoided.

In the second embodiment, as shown in fig. 1-2, the instrument panel 21 is installed on the top of the 5G detector 2 through the extension rod, the arc-shaped gaps corresponding to the flange coil 11 and the extension rod of the instrument panel 21 are provided on the abutting surface of the two protective housings 4, the elastic compression pad 41 is adhered on the abutting surface of the two protective housings 4, the arc-shaped plates 42 are respectively fixed on the top surfaces of the two protective housings 4, the corresponding external threads are provided on the two arc-shaped plates 42 and are spliced together, the instrument panel 21 is enclosed inside the two arc-shaped plates 42, the two arc-shaped plates 42 are connected with the transparent cylinder 43 in a common thread manner, the side wall of the protective housing 4 is provided with the opening, the shutter 44 is nailed on the outer side of the protective housing 4, the heat dissipation fan 45 is installed on the inner wall of the protective housing 4, the temperature sensor 46 is installed on the inner bottom surface of the protective housing 4, the temperature sensor 46 is in telecommunication connection with the heat dissipation fan 45, the buzzer 47 and the alarm flash lamp 48 are respectively installed on the front surfaces of the two protective housings 4, the buzzer 47 and the alarm flash lamp 48 are electrically connected with the 5G detector 2, and the buzzer 47 and the alarm flash lamp 48 pass through the two gaps of the alarm housing 4.

The specific operation is as follows, on the sealed protection optimal design of protective housing 4, arc breach makes protective housing 4 better with connect the pole laminating of pole to flange coil 11 and panel board 21, and elasticity tight pressure pad 41 can improve the leakproofness of concatenation, because panel board 21 exposes outside, consequently, can protect the dust through arc 42 and transparent drum 43, and transparent drum 43 of transparent material preparation does not influence and watch, and on the heat dissipation design, shutter plate 44 can play ventilation radiating effect, be convenient for signal transmission simultaneously, and when the higher natural convection effect of ambient temperature is relatively poor, temperature sensor 46 can detect the temperature, start radiating fan 45 when reaching certain formulation numerical value strengthen convection heat dissipation can, avoid giving off heat because protective housing 4's protection is difficult to, this is prior art means, finally on alarm suggestion optimal design, buzzer 47 and alarm flashing lamp 48 can sound and scintillation when 5G detector 2 detects pressure anomaly, then make the suggestion effect improve greatly, when the installation, firstly, directly connect the junction of buzzer 47 and alarm flashing lamp 48 with 5G detector 2, thereby in the convenient butt joint of its butt joint face of protective housing 4.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a natural gas pipeline pressure detection controlling means based on 5G, includes pipeline main part (1) and 5G detector (2) and fixed plate (6), and on flange coil (11) at pipeline main part (1) top was installed to 5G detector (2), fixed plate (6) nail connect subaerial in pipeline main part (1) below, its characterized in that: the utility model discloses a pipeline main part, including pipeline main part (1), arc board (3) are installed to pipeline main part (1) both sides, two arc board (3) top is fixed with protective housing (4), protective housing (4) splice each other and cover 5G detector (2) inside, install assembly (5) between arc board (3) and fixed plate (6), assembly (5) are including welding screw rod A (51) at fixed plate (6) top surface, screw rod A (51) top is equipped with screw rod B (52), screw rod B (52) and screw rod A (51) common threaded connection have locating sleeve (53), and screw rod B (52) welding is in arc board (3) bottom.

2. The 5G-based natural gas pipeline pressure detection control device according to claim 1, wherein a ring plate (54) is fixed to a portion, which is not threaded, of the upper end of the screw rod B (52), an annular sleeve (55) is slidably connected to the screw rod B (52) above the ring plate (54), four inserting rods (56) are uniformly fixed to the bottom of the annular sleeve (55), the inserting rods (56) penetrate through the annular plate (54) to be inserted into round holes in the top of the positioning sleeve (53), springs (57) sleeved outside the inserting rods (56) are fixed to the annular sleeve (55) and the ring plate (54), and the top surface of the annular sleeve (55) is attached to the bottom surface of the ring plate (54).

3. The 5G-based natural gas pipeline pressure detection control device according to claim 1, wherein an instrument panel (21) is installed at the top of the 5G detector (2) through a connecting rod, arc-shaped notches corresponding to the flange coil (11) and the connecting rod of the instrument panel (21) are formed on the butt joint surfaces of the two protective shells (4), and elastic compression pads (41) are adhered to the butt joint surfaces of the two protective shells (4).

4. A natural gas pipeline pressure detection control device based on 5G according to claim 3, wherein the top surfaces of the two protective shells (4) are respectively fixed with an arc plate (42), the two arc plates (42) are provided with corresponding external threads and are spliced together, the two arc plates (42) enclose the instrument panel (21) inside, and the two arc plates (42) are connected with a transparent cylinder (43) in a threaded manner.

5. The 5G-based natural gas pipeline pressure detection control device according to claim 4, wherein the side wall of the protective housing (4) is provided with an opening, and the protective housing (4) is nailed with a louver (44) at a position outside the opening.

6. A natural gas pipeline pressure detection control device based on 5G according to claim 5, wherein a heat dissipation fan (45) is mounted on the inner wall of the protective housing (4), and a temperature sensor (46) is mounted on the inner bottom surface of the protective housing (4), and the temperature sensor (46) is in telecommunication connection with the heat dissipation fan (45).

7. The natural gas pipeline pressure detection control device based on 5G according to claim 5, wherein a buzzer (47) and an alarm flashing lamp (48) are respectively installed on the front surfaces of the two protective shells (4), the buzzer (47) and the alarm flashing lamp (48) are electrically connected with the 5G detector (2), and wiring of the buzzer (47) and the alarm flashing lamp (48) and the 5G detector (2) penetrates through gaps of the butt joint surfaces of the two protective shells (4).