CN220288929U - Fire control pipeline detector - Google Patents

Abstract

The utility model relates to a pipeline detection's technical field specifically is a fire control pipeline detector, including the pipeline truss, pipeline truss upper end fixed mounting has the slope pipeline truss rail, the detection slide rail is all installed to pipeline truss both sides, detect the slide rail and install respectively and exert pressure end and detection end, the end of exerting pressure includes the pressure disc, pressure disc middle part fixedly connected with air cock, the air cock is connected with the air pump, the detection end includes the pressure bearing dish, fixedly connected with manometer on the pressure bearing dish, the pressure end is all installed in detecting the slide rail with the detection end slidable, install driving cylinder on the detection slide rail, pipeline truss middle part rotatable mounting has the driving shaft, driving shaft is connected with driving motor, install the driving arc claw on the driving shaft, driving arc claw is semicircle annular, multiunit driving arc claw circumference array is in driving the pipe outside. The air tightness detection is automatically carried out on the fire fighting pipeline according to the sequence through the pipe poking shaft and the pipe poking arc claw, so that the detection efficiency of the fire fighting pipeline is improved.

Description

Fire control pipeline detector

Technical Field

The application relates to the technical field of pipeline detection, in particular to a fire-fighting pipeline detector.

Background

A fire pipe is a water pipe installed in fire engineering for use in a fire or other safety facility where water is required.

At present, the floor is generally higher, water is required to be increased to the high position of the floor, the pipeline is required to have better air tightness and compression resistance, so that the water cannot reach the height and even leak due to pressure loss, the air tightness of the pipeline is required to be checked before the fire-fighting pipeline is constructed, but the current fire-fighting pipeline detector is lower in automation degree and slower in detection speed.

Disclosure of Invention

Aiming at the defects in the prior art, the purpose of the application is to provide a fire-fighting pipeline detector with improved detection efficiency.

The above application object of the present application is achieved by the following technical solutions:

a fire pipe detector, comprising:

the pipeline truss is provided with a rectangular frame;

the pipeline truss rails are arranged in parallel, are fixedly arranged at the upper ends of the pipeline truss rails and are in an inclined state;

the two detection slide rails are respectively arranged at the positions of the two sides of the pipeline truss and positioned in the middle of the pipeline truss;

the pressing end comprises a pressing disc, a sealing gasket is arranged on the end face of the pressing disc, an air tap is fixedly connected to the middle of the pressing disc, the air tap is connected with an air pump, and the pressing end is slidably arranged on one of the detection slide rails;

the detection end comprises a pressure bearing disc, a sealing gasket is arranged on the end face of the pressure bearing disc, a pressure gauge is fixedly connected to the pressure bearing disc, and the detection end is slidably arranged on the detection sliding rail far away from the pressure applying end;

the pipe shifting shaft is rotatably arranged in the middle of the pipeline truss, two ends of the pipe shifting shaft are respectively positioned at the positions of the pressing end and the detecting end, and the pipe shifting shaft is connected with a driving motor;

the tube poking arc claws are semicircular, a plurality of groups of tube poking arc claws are circumferentially arrayed outside the tube poking shaft, and the inner side surfaces of the tube poking arc claws are far away from the tube poking shaft;

the detection sliding rail is provided with a driving cylinder, and the driving cylinder drives the pressing end or the detection end to slide.

Optionally, the detection slide rail upper end all can install the alignment jig in a sliding way, drive cylinder connect in the alignment jig, the end of exerting pressure and detection respectively liftable install in the alignment jig.

Optionally, a ball screw mechanism is installed on the adjusting frame, the ball screw mechanism comprises a sliding block and a screw rod, the pressing end and the detecting end are respectively installed on the sliding block, and one end of the screw rod is fixedly connected with a rotating handle.

Optionally, one side of the screw rod is provided with a scale.

Optionally, the manometer is the electronic pressure gauge, the pipeline truss is installed the siren, the manometer with the siren signal connection.

Optionally, pipeline truss fixed mounting has the mounting, mounting detachably installs the piece that sprays paint, mounting fixedly connected with pneumatic press piece, pneumatic press piece output connect in the piece that sprays paint, the manometer with pneumatic press piece electrical signal connection.

Optionally, at least two tube-poking arc claws are arranged in each group, and the tube-poking arc claws are uniformly distributed on the tube poking shaft.

Optionally, the tube-pulling arc claw is slidably mounted on the tube-pulling shaft.

In summary, the present application includes at least one of the following beneficial technical effects:

the inclined pipeline truss rail is arranged to enable the fire-fighting pipeline to roll down automatically, the pipe poking shaft rotates to enable the pipe poking arc claw to poke up the fire-fighting pipeline to the pressing end and the detecting end, after detection, the pipe poking shaft rotates to put down the detected fire-fighting pipeline, and simultaneously poking up another fire-fighting pipeline to detect, and the pipe poking shaft and the pipe poking arc claw are used for automatically detecting the air tightness of the fire-fighting pipeline in sequence, so that the detection efficiency of the fire-fighting pipeline is improved;

by arranging the liftable pressure applying end and the detection end, the pressure applying plate, the pressure bearing plate and the pipeline can be adjusted to be coaxial when fire-fighting pipelines with different diameters are detected, so that the fire-fighting pipeline is convenient to adapt to different pipeline use requirements and can be better sealed;

through setting up spray painting spare and alarm, at automated inspection's in-process, through the information feedback of manometer, carry out spraying mark and warning to unqualified pipeline to the staff distinguishes.

Drawings

FIG. 1 is a schematic overall structure of an embodiment of the present application;

FIG. 2 is a schematic structural view of a detection rail portion according to an embodiment of the present disclosure;

fig. 3 is a schematic structural view of a dial shaft portion according to an embodiment of the present application.

Reference numerals: 1. a pipe truss;

21. pipeline truss rail; 22. detecting a sliding rail; 221. an adjusting frame;

31. a pressing end; 311. shi Yapan; 312. an air tap; 32. a detection end; 321. a pressure-bearing disc; 322. a pressure gauge; 33. a driving cylinder;

4. a tube-shifting shaft; 41. a pipe poking arc claw;

51. a fixing member; 52. a painting member; 53. pneumatic pressing piece.

Description of the embodiments

The present application is described in further detail below with reference to the accompanying drawings.

Referring to fig. 1, a fire fighting pipeline detector disclosed in the embodiments of the present application includes a pipeline truss 1, the pipeline truss 1 is a rectangular frame, the upper end of the pipeline truss 1 is fixedly provided with two pipeline truss rails 21, the two pipeline truss rails 21 are parallel, the pipeline truss rails 21 are in an inclined state, the two sides of the pipeline truss 1 are located at the middle of the pipeline truss rails 21, the detection slide rails 22 are respectively provided with a pressure applying end 31 and a detection end 32, the pressure applying end 31 includes a pressure applying plate 311, the middle of the pressure applying plate 311 is fixedly connected with an air tap 312, the air tap 312 is connected with an air pump, referring to fig. 2, the detection end 32 includes a pressure bearing plate 321, the pressure bearing plate 321 is fixedly connected with a pressure gauge 322, the end faces of the pressing end 31 opposite to the pressure-bearing disc 321 are respectively provided with a sealing gasket, the pressing end 31 and the detecting end 32 are slidably arranged on the detecting slide rail 22, a driving cylinder 33 is arranged on the detecting slide rail 22, the driving cylinder 33 drives the pressing end 31 or the detecting end 32 to slide, a pipe shifting shaft 4 is rotatably arranged in the middle of the pipe truss 1, two ends of the pipe shifting shaft 4 are respectively positioned at the positions of the pressing end 31 and the detecting end 32, the pipe shifting shaft 4 is connected with a driving motor, referring to fig. 3, pipe shifting arc claws 41 are arranged on the pipe shifting shaft 4, the pipe shifting arc claws 41 are semicircular, a plurality of groups of pipe shifting arc claws 41 are circumferentially arrayed on the outer side of the pipe shifting shaft 4, and the inner side faces of the pipe shifting arc claws 41 are far away from the pipe shifting shaft 4.

Specifically, the obliquely downward pipeline truss rail 21 is arranged on the pipeline truss 1 and used for placing a fire-fighting pipeline, the pipe pulling shaft 4 is arranged in the middle of the pipeline truss 1, the pipe pulling arc claw 41 is arranged on the pipe pulling shaft 4, the pipe pulling arc claw 41 is used for distributing the fire-fighting pipeline, when the pipe pulling arc claw 41 is used for pulling the fire-fighting pipeline between the pressure applying end 31 and the detecting end 32, the pipe pulling arc claw 41 is clamped on two sides of the fire-fighting pipeline through the Shi Yapan and the pressure-bearing disc 321, and the pressure applying disc 311 is used for inflating and detecting air pressure through the pressure gauge 322.

In this way, the inclined pipeline truss rail 21 is arranged to enable the fire-fighting pipeline to roll down automatically, the pipe poking shaft 4 rotates to enable the pipe poking arc claw 41 to poke the fire-fighting pipeline to the pressing end 31 and the detecting end 32, after detection, the pipe poking shaft 4 rotates to put down the detected fire-fighting pipeline, and simultaneously poking up another fire-fighting pipeline to detect, and the pipe poking shaft 4 and the pipe poking arc claw 41 are used for sequentially and automatically detecting the air tightness of the fire-fighting pipeline, so that the detection efficiency of the fire-fighting pipeline is improved.

In some possible modes, the pipe truss 1 is a rectangular frame, the pipe truss 1 is obliquely arranged at the upper end of the pipe truss 1, so that a fire-fighting pipe can roll off automatically when placed, the pipe poking shaft 4 is a cylindrical shaft and is driven to rotate on the pipe truss 1 by a driving motor, as shown in fig. 3, the number of pipe poking arc claws 41 is six, the circumference of the pipe poking arc claws are arranged at the outer side of the pipe poking shaft 4 in an array manner, and in order to improve the continuity of poking pipes, the end positions of adjacent pipe poking arc claws 41 are mutually attached and fixed;

referring to fig. 2, the pressing disc 311 and the pressure bearing disc 321 are disc-shaped, and slidably mounted on the detecting slide rail 22 through a rectangular support frame, and a driving cylinder 33 is disposed between the detecting slide rail 22 and the rectangular support frame, so that the pressing disc 311 and the pressure bearing disc 321 can be closely attached to two ends of a fire fighting pipeline, and further, sealing gaskets are disposed on opposite end surfaces of the pressing end 31 and the pressure bearing disc 321.

Further description will be provided below in connection with specific use cases.

When the fire-fighting pipeline is used, the fire-fighting pipeline is arranged on the pipeline truss rail 21, the fire-fighting pipeline rolls down side by side to the position of the pipe poking arc claw 41 and is clamped by the pipe poking arc claw 41, the pipe poking shaft 4 rotates to drive the pipe poking arc claw 41 to rotate, the fire-fighting pipeline rolls down to the position in one pipe poking arc claw 41 and is brought between the pressing end 31 and the detecting end 32, the driving cylinder 33 drives the pressing end 31 and the detecting end 32 to be attached to two ends of the fire-fighting pipeline and to be sealed under pressure, gas is injected through the gas tap 312, and the pressure after a period of time is detected through the pressure gauge 322, so that whether the pressure loss exists is judged. Then the driving cylinder 33 drives the pressing end 31 and the detecting end 32 to move backwards, the pipe poking arc claw 41 rotates the fire fighting pipeline to the other side of the pipeline truss rail 21, and meanwhile, the other pipe poking arc claw 41 brings the other fire fighting pipeline between the pressing end 31 and the detecting end 32.

As a specific embodiment of a fire fighting pipeline detector provided in the application, referring to fig. 2, an adjusting frame 221 is slidably mounted at the upper end of the detecting slide rail 22, a driving cylinder 33 is connected to the adjusting frame 221, and a pressing end 31 and a detecting end 32 are respectively mounted on the adjusting frame 221 in a liftable manner.

In the whole, the pressure applying end 31 and the detecting end 32 are used for sealing two ends of the fire-fighting pipeline through the pressure applying disc 311 and the pressure bearing disc 321 so as to carry out an air tightness experiment, and the pressure applying disc 311, the pressure bearing disc 321 and the pipeline can be adjusted to be coaxial when fire-fighting pipelines with different diameters are detected by arranging the liftable pressure applying end 31 and the detecting end 32, so that different pipeline use requirements can be met and better sealing can be carried out.

Further, a ball screw mechanism is mounted on the adjusting frame 221, the ball screw mechanism comprises a sliding block and a screw rod, the pressing end 31 and the detecting end 32 are respectively mounted on the sliding block, and one end of the screw rod is fixedly connected with a rotating handle.

It should be appreciated that by providing a ball screw mechanism and a rotating handle, the adjustment and locking of the height of the pressing end 31 and the detecting end 32 is facilitated.

Further, in order to facilitate accurate adjustment of the height, one side of the screw rod is provided with a scale.

In some possible ways, the adjusting frame 221 is a rectangular frame, the detecting slide rail 22 comprises two parallel square rails, the lower side of the adjusting frame 221 is sleeved on the square rails through square pipes, the pressure applying end 31 and the detecting end 32 are installed on one side, close to the pipeline truss rail 21, of the adjusting frame 221 and fixedly connected with sliding blocks, in order to improve the sealing effect in pressure sealing, sliding rods are arranged on two sides of the ball screw mechanism, sliding blocks are slidably arranged on the sliding rods, and the sliding blocks are fixedly connected to the pressure applying end 31 or the detecting end 32.

As another specific embodiment of a fire fighting pipeline detector provided by the application, the pressure gauge 322 is an electronic pressure gauge, the pipeline truss 1 is provided with an alarm, and the pressure gauge 322 is connected with an alarm electric signal.

It should be appreciated that by providing an alarm, when the pressure gauge 322 detects an abnormal airtight condition, a signal is fed back to the alarm to alert the staff.

Further, referring to fig. 3, the pipe truss 1 is fixedly provided with a fixing member 51, the fixing member 51 is detachably provided with a paint spraying member 52, the fixing member 51 is fixedly connected with a pneumatic pressing member 53, an output end of the pneumatic pressing member 53 is connected with the paint spraying member 52, and the pressure gauge 322 is electrically connected with the pneumatic pressing member 53.

It will be appreciated that by providing the painting member 52, the failed pipe is painted and marked during the automatic inspection process by the feedback of the pressure gauge 322 information to facilitate the staff to distinguish.

In some possible ways, the pressure gauge 322 is connected with a single-chip microcomputer control module, and the control module is connected with a control alarm and a pneumatic pressing piece 53. The fixing piece 51 is a C-shaped pipe hoop fixedly arranged on the upper side of the pipe truss 1 and used for fixing the paint spraying piece 52, the paint spraying piece 52 can be selected as self-spraying paint, and the pneumatic pressing piece 53 can be selected as an air cylinder.

As a specific embodiment of the fire fighting pipeline detector provided by the application, at least two pipe poking arc claws 41 are arranged in each group, and the pipe poking arc claws 41 are uniformly distributed on the pipe poking shaft 4.

It will be appreciated that by evenly arranging the plurality of tube fingers 41, the likelihood of tilting the fire tube as it is being carried up is reduced.

Further, a tube-pulling arc claw 41 is slidably mounted to the tube-pulling shaft 4.

It will be appreciated that by providing slidably tube fingers 41, the spacing between the tube fingers 41 is facilitated to be adjusted for fire tubes of different lengths.

In some possible modes, a trapezoid groove is formed in the side face of the tube poking shaft 4 along the axial direction, a trapezoid block is fixedly connected to one side of the tube poking arc claw 41, which is close to the tube poking shaft 4, and the trapezoid block is slidably arranged in the trapezoid groove.

The embodiments of the present utility model are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in this way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (8)

1. A fire pipe detector, comprising:

the pipeline truss (1), wherein the pipeline truss (1) is a rectangular frame;

the pipeline truss rails (21) are arranged in parallel, the two pipeline truss rails (21) are fixedly arranged at the upper end of the pipeline truss (1), and the pipeline truss rails (21) are in an inclined state;

the two detection slide rails (22) are respectively arranged at the positions of the two sides of the pipeline truss (1) and positioned in the middle of the pipeline truss rail (21);

the pressing end (31), the pressing end (31) comprises a Shi Yapan (311), a sealing gasket is arranged on the end face of the pressing disc (311), an air tap (312) is fixedly connected to the middle of the pressing disc (311), the air tap (312) is connected with an air pump, and the pressing end (31) is slidably arranged on one of the detection slide rails (22);

the detection end (32), the detection end (32) comprises a pressure-bearing disc (321), a sealing gasket is arranged on the end face of the pressure-bearing disc (321), a pressure gauge (322) is fixedly connected to the pressure-bearing disc (321), and the detection end (32) is slidably arranged on the detection slide rail (22) far away from the pressure-bearing end (31);

the pipe shifting shaft (4) is rotatably arranged in the middle of the pipeline truss (1), two ends of the pipe shifting shaft (4) are respectively positioned at the positions of the pressing end (31) and the detecting end (32), and the pipe shifting shaft (4) is connected with a driving motor;

the pipe poking arc claws (41) are semicircular, a plurality of groups of pipe poking arc claws (41) are circumferentially arrayed outside the pipe poking shaft (4), and the inner side surfaces of the pipe poking arc claws (41) are far away from the pipe poking shaft (4);

the detection slide rail (22) is provided with a driving cylinder (33), and the driving cylinder (33) drives the pressing end (31) or the detection end (32) to slide.

2. A fire pipe detector according to claim 1, wherein: the upper ends of the detection slide rails (22) are slidably provided with adjusting frames (221), the driving air cylinders (33) are connected to the adjusting frames (221), and the pressing ends (31) and the detection ends (32) are respectively arranged on the adjusting frames (221) in a lifting mode.

3. A fire pipe detector according to claim 2, wherein: the ball screw mechanism is arranged on the adjusting frame (221) and comprises a sliding block and a screw rod, the pressing end (31) and the detecting end (32) are respectively arranged on the sliding block, and one end of the screw rod is fixedly connected with a rotating handle.

4. A fire pipe detector according to claim 3, wherein: one side of the screw rod is provided with a scale.

5. A fire pipe detector according to claim 1, wherein: the pressure gauge (322) is an electronic pressure gauge, the pipeline truss (1) is provided with an alarm, and the pressure gauge (322) is electrically connected with the alarm.

6. A fire pipe detector according to claim 5, wherein: the pipeline truss (1) is fixedly provided with a fixing piece (51), the fixing piece (51) is detachably provided with a paint spraying piece (52), the fixing piece (51) is fixedly connected with a pneumatic pressing piece (53), the output end of the pneumatic pressing piece (53) is connected with the paint spraying piece (52), and the pressure gauge (322) is electrically connected with the pneumatic pressing piece (53).

7. A fire pipe detector according to claim 1, wherein: each group of pipe poking arc claws (41) is provided with at least two, and the pipe poking arc claws (41) are uniformly distributed on the pipe poking shaft (4).

8. A fire pipe detector according to claim 7, wherein: the tube-shifting arc claw (41) is slidably mounted on the tube-shifting shaft (4).