CN213040323U - Monitoring assembly of conveying pipeline - Google Patents

Abstract

The utility model provides a pipeline's control subassembly relates to the pipeline field. The monitoring assembly of the conveying pipeline comprises a tubular shell and a monitoring structure, wherein a first pipe joint and a second pipe joint are respectively arranged at two ends of the tubular shell, and a conveying channel for moving materials is arranged in the tubular shell; the pipe wall of the tubular shell is provided with a monitoring window, a window outer cover is installed at the position of the monitoring window, an accommodating space is formed inside the window outer cover and is located outside the conveying channel, the monitoring structure is installed in the accommodating space, and a material guide plate used for pressing and finishing materials is arranged on one side, corresponding to supplied materials, of the inside of the accommodating space. The tubular shell is connected in series on the conveying pipeline, and the window outer cover has a sealing effect on the monitoring window to prevent the material from leaking out of the monitoring window; the window outer cover is utilized to construct the accommodating space outside the monitoring window, so that the conveying condition of materials in the pipe can be directly monitored, the monitoring structure is prevented from protruding into a conveying channel, and the problem of pipeline blockage is avoided.

Description

Monitoring assembly of conveying pipeline

Technical Field

The utility model relates to a pipeline technical field especially relates to a pipeline's control subassembly.

Background

Pipeline transport is a common material transport mode, and when utilizing the pipeline transport material, especially, the problem of jam often can appear when carrying solid material, for the unobstructed degree in the control pipe, can set up corresponding detection device in the pipeline.

If chinese utility model patent that the bulletin number is CN205402248U, the bulletin date is 2016.07.27 discloses a novel pipeline detection device, and specifically disclose including main control unit, still included a plurality of pressure acquisition sensors of evenly arranging along the length direction of pipeline respectively, from the controller of being connected with pressure sensor's output and with from the communication end of controller be connected from wireless communication module, main control unit's output is connected with the LCD display, main control unit's communication end is connected with main wireless communication module, and main wireless communication module still carries out wireless communication with pressure acquisition mechanism from between the wireless communication module, still be equipped with waterproof camera on the pipe inner wall that lies in pressure sensor department, its outside still is equipped with transparent protection casing, still be connected with the memory at the output from the controller. When a certain section of pipeline is blocked, the pressure sensors at two ends of the pipeline section generate obvious pressure difference, so that the blocking condition of the pipeline section can be effectively detected; through being equipped with waterproof camera, alright carry out audio-visual observation to the jam condition of pipeline inside.

Use the pipe blockage detection device among the prior art, usable pressure sensor and waterproof camera confirm the intraductal jam condition, but, directly set up the inner wall that monitoring structure can cause the pipeline in the pipeline and form the bulge, the bulge interferes the normal transport of material to the problem of pipe blockage has been initiated from this.

SUMMERY OF THE UTILITY MODEL

In order to solve the above problem, an object of the present invention is to provide a monitoring assembly for a conveying pipeline, which is to solve the problem that the inner wall of the pipeline forms a bulge part when the monitoring structure is directly arranged in the pipeline, and the bulge part interferes with the normal conveying of the material, thereby causing the problem of pipeline blockage.

The utility model discloses a pipeline's control subassembly's technical scheme does:

the monitoring assembly of the conveying pipeline comprises a tubular shell and a monitoring structure, wherein a first pipe joint and a second pipe joint are respectively arranged at two ends of the tubular shell, and a conveying channel for moving materials is arranged in the tubular shell; the pipe wall of the tubular shell is provided with a monitoring window, a window outer cover is arranged at the monitoring window, an accommodating space is formed inside the window outer cover and is located outside the conveying channel, the monitoring structure is arranged in the accommodating space, and a material guide plate used for pressing and finishing materials is arranged on one side, corresponding to supplied materials, inside the accommodating space.

Has the advantages that: the tubular shell is connected with the conveying pipeline in series through the first pipe connector and the second pipe connector, the window outer cover is arranged at the monitoring window of the tubular shell, the monitoring window is sealed, and materials are prevented from leaking out of the monitoring window; more importantly, utilize the window dustcoat to establish the accommodation space in monitor window's the outside, the accommodation space is located beyond the transfer passage and communicates with each other with transfer passage, the control structure is installed in the accommodation space, not only can directly monitor the transport condition of intraductal material, whether unobstructed effectively detect out pipeline's inside, still avoided the control structure to bulge to transfer passage in, prevent that the normal transport of control structure itself to the material from causing the interference influence, ensure to be unlikely to arouse the problem of pipe blockage.

Furthermore, the window outer cover comprises a window coaming and a cover plate, the window coaming is fixedly connected to the pipe wall of the tubular shell, and the cover plate is mounted on the window coaming in a buckling manner.

Further, the tubular shell is a circular tube shell, the monitoring window is a rectangular window formed in the tube wall of the circular tube shell, and the window coaming is rectangular in outline and surrounds the edge of the monitoring window.

Furthermore, the monitoring structure is installed on the cover plate, a cover plate turning edge is arranged at the edge of the cover plate, and the cover plate turning edge is sleeved on the outer side of the window enclosing plate when the cover plate is buckled.

Furthermore, the cover plate turning edge and the window enclosing plate are detachably connected.

Furthermore, a first bolt hole is formed in the window enclosing plate, a second bolt hole is formed in the cover plate turning edge, and a connecting bolt penetrates through the first bolt hole and the second bolt hole.

Further, the material guide plate inclines inwards along the feeding direction of the conveying channel, and the monitoring structure is higher than or flush with the bottom edge of the material guide plate.

Further, the inclined included angle between the material guide plate and the axis of the conveying channel is any angle between 5 degrees and 45 degrees.

Further, the monitoring structure comprises a camera and a sensor, and the shooting direction of the camera corresponds to the feeding direction of the conveying channel.

Further, the sensor is at least one of a pressure sensor, a flow sensor, a temperature sensor and a humidity sensor.

Drawings

Fig. 1 is a schematic perspective view of a monitoring assembly according to an embodiment 1 of the monitoring assembly of the present invention;

fig. 2 is a schematic perspective view of a monitoring assembly (without a cover plate) in an embodiment 1 of the monitoring assembly for a conveying pipeline according to the present invention;

fig. 3 is a schematic cross-sectional view of a monitoring assembly according to embodiment 1 of the monitoring assembly of the present invention;

fig. 4 is an explosion diagram of the monitoring assembly according to embodiment 1 of the monitoring assembly of the present invention.

In the figure: the monitoring system comprises a tubular shell, a conveying channel, a first pipe joint, a second pipe joint, a monitoring window, a window cover, a containing space, a window enclosing plate, a first bolt hole, a second bolt hole, a sealing cover plate, a cover plate turning edge, a connecting bolt, a guide plate, a monitoring structure, a camera, a pressure sensor and a flow sensor, wherein the tubular shell is 1 part, the conveying channel is 10 parts, the first pipe joint is 11 parts, the second pipe joint is 12 parts, the monitoring window is 13 parts, the window cover is 2 parts, the containing.

Detailed Description

The following detailed description of the embodiments of the present invention is provided with reference to the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

In the embodiment 1 of the monitoring assembly of the conveying pipeline of the present invention, as shown in fig. 1 to 4, the monitoring assembly of the conveying pipeline includes a tubular housing 1 and a monitoring structure 3, a first pipe interface 11 and a second pipe interface 12 are respectively disposed at two ends of the tubular housing 1, and a conveying passage 10 for moving a material is disposed inside the tubular housing 1; the pipe wall of the tubular shell 1 is provided with a monitoring window 13, the monitoring window 13 is provided with a window outer cover 2, an accommodating space 20 outside the conveying channel 10 is formed inside the window outer cover 2, the monitoring structure 3 is installed in the accommodating space 20, and a material guide plate 25 for pressing and shaping materials is arranged on one side, corresponding to supplied materials, inside the accommodating space 20. The tubular shell 1 is connected in series on the conveying pipeline through the first pipe connector 11 and the second pipe connector 12, the accommodating space 20 is communicated with the conveying channel 10, and the monitoring structure 3 in the accommodating space 20 can effectively detect whether the inside of the conveying pipeline is smooth or not.

In this embodiment, the window enclosure 2 includes a window enclosing plate 21 and a cover plate 22, the window enclosing plate 21 is fixedly connected to the tube wall of the tubular housing 1, and the cover plate 22 is snap-fitted on the window enclosing plate 21. Specifically, the tubular housing 1 is a circular tube housing, the monitoring window 13 is a rectangular window formed in the wall of the circular tube housing, and the window enclosure 21 surrounds the edge of the monitoring window 13 in a rectangular profile. Namely, the window enclosing plate 21 comprises four side plates which are sequentially fixedly connected and are rectangular, wherein the four side plates are a left side plate, a right side plate, a front side plate and a rear side plate respectively, the left side plate and the right side plate are vertically arranged in parallel to the axis direction of the conveying channel 10, and the lower edges of the left side plate and the right side plate are respectively fixedly connected with two straight edges of the monitoring window 13; the front side plate and the rear side plate are vertically arranged perpendicular to the axial direction of the conveying passage 10, and the lower edges of the front side plate and the rear side plate are fixedly connected with two circular arc-shaped edges of the monitoring window 13 respectively.

The monitoring structure 3 is installed on the cover plate 22, the edge of the cover plate 22 is provided with a cover plate turning edge 23, and the cover plate turning edge 23 is sleeved on the outer side of the window enclosing plate 21 when the cover plate 22 is buckled. And the cover plate turning edge 23 of the cover plate 22 is detachably connected with the window enclosing plate 21. The cover plate 22 is fixedly connected to the monitoring window 13 of the tubular shell 1 through the window enclosing plate 21, and the cover plate 22 is mounted on the window enclosing plate 21, so that the monitoring window 13 is sealed, and materials are prevented from leaking out of the monitoring window 13. More importantly, the window outer cover 2 is utilized to construct the accommodating space 20 outside the monitoring window 13, the accommodating space 20 is positioned outside the conveying channel 10 and communicated with the conveying channel 10, and the monitoring structure 3 is installed in the accommodating space 20, so that the conveying condition of materials in the pipe can be directly monitored, the monitoring structure 3 is prevented from protruding into the conveying channel 10, the interference influence on the normal conveying of the materials caused by the monitoring structure 3 is prevented, and the problem of pipeline blockage is avoided.

The window enclosing plate 21 is provided with a first bolt hole 210, the cover plate turning edge 23 is provided with a second bolt hole 230, and the first bolt hole 210 of the window enclosing plate 21 and the second bolt hole 230 of the cover plate turning edge 23 are provided with connecting bolts 24 in a penetrating way. During installation, the cover plate 22 is fastened to the window enclosing plate 21, aligned with the first bolt hole 210 of the window enclosing plate 21 and the second bolt hole 230 of the cover plate flange 23, and penetrates through the installation connecting bolt 24 so as to fix the cover plate 22 on the window enclosing plate 21. When needed, the connecting bolt 24 can be detached, the sealing cover plate 22 is taken down to open the accommodating space 20, the monitoring structure 3 is convenient to overhaul and adjust, and workers can conveniently enter the conveying channel 10 through the monitoring window 13 to conduct subsequent dredging and material removing operation.

Wherein the material guide plate 25 is inclined inwards in the feeding direction of the conveying channel 10, and the monitoring structure 3 is higher than or flush with the bottom edge of the material guide plate 25. In this embodiment, the inclined included angle between the guide plate 25 and the axis of the conveying channel 10 is 30 °, when the material moves to the monitoring window 13, since the accommodating space 20 is communicated with the conveying channel 10, in order to avoid the material from entering the accommodating space 20 due to lack of constraint of the pipe wall, the guide plate 25 arranged obliquely guides and presses a part of the material close to the monitoring window 13, so as to ensure that the material is not in contact with the monitoring structure 3, and improve the smoothness of material conveying and the reliability of the monitoring structure 3.

In the present embodiment, the monitoring structure 3 includes a camera 31 and a sensor, and the shooting direction of the camera 31 corresponds to the feeding direction of the conveying passage 10. The material pressed and integrated by the material guide plate 25 may swell again, so as to prevent the swelled material from being blocked by the camera 31 and being accumulated on the lens, the material guide plate 25 is disposed inside the accommodating space 20 corresponding to the incoming material side, the shooting direction of the camera 31 corresponds to the feeding direction of the conveying channel 10, that is, the shooting direction of the camera 31 is arranged back to the material guide plate 25, so that the problem that the material blocks the lens of the camera 31 is effectively avoided. And, the sensor is equipped with two, and two sensors are pressure sensor 32 and flow sensor 33 respectively, and pressure sensor 32 is used for detecting the inside air pressure of transfer passage 10, and flow sensor 33 is also called as the air velocity transducer for detecting the inside air current parameter of transfer passage 10 to combine the video image acquisition function of camera 31, under the circumstances that the staff does not open the transfer passage, can confirm whether smooth inside the transfer passage according to the video image of passback, air pressure and air current parameter.

The utility model discloses a pipeline's other embodiments of control subassembly, in order to satisfy different user demands, the structure of window dustcoat is not only limited to the form that window bounding wall adds the closing cap board among embodiment 1, still can be with the design of window dustcoat for uncovered box body structure, and control structure fixed mounting is in the inside of uncovered box body structure, with the direct spiral-lock of uncovered box body structure in the control window department of tubulose casing to play effective closure effect to the control window. In addition, any connection form such as welding connection, bolt connection or buckling connection can be adopted between the window outer cover of the uncovered box body structure and the tubular shell.

The utility model discloses a pipeline's other embodiments of control subassembly, in order to satisfy different user demands, inclination between stock guide and transfer passage's the axis is not only limited to 30 in embodiment 1, still can design 5, 45 with the stock guide, perhaps, other arbitrary angles between 5 to 45, can play the effect of guide and pressure material equally, prevent that monitoring structure 3 from taking place to interfere the influence to the material in the removal.

In order to meet different use requirements, the types and the number of the sensors are not limited to the pressure sensor and the flow sensor in embodiment 1, and any one of the pressure sensor, the flow sensor, the temperature sensor and the humidity sensor can be arranged in the accommodating space; or any two or more of a pressure sensor, a flow sensor, a temperature sensor and a humidity sensor, thereby more comprehensively acquiring various parameters in the conveying channel.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and replacements can be made without departing from the technical principle of the present invention, and these modifications and replacements should also be regarded as the protection scope of the present invention.

Claims (10)

1. A monitoring assembly of a conveying pipeline is characterized by comprising a tubular shell and a monitoring structure, wherein a first pipe joint and a second pipe joint are respectively arranged at two ends of the tubular shell, and a conveying channel for moving materials is arranged in the tubular shell; the pipe wall of the tubular shell is provided with a monitoring window, a window outer cover is arranged at the monitoring window, an accommodating space is formed inside the window outer cover and is located outside the conveying channel, the monitoring structure is arranged in the accommodating space, and a material guide plate used for pressing and finishing materials is arranged on one side, corresponding to supplied materials, inside the accommodating space.

2. A pipeline monitoring assembly as claimed in claim 1, wherein the window enclosure comprises a window shroud fixedly attached to the wall of the tubular housing and a cover plate snap-fitted over the window shroud.

3. The monitoring assembly of claim 2, wherein the tubular housing is a round tubular housing, the monitoring window is a rectangular window formed in a wall of the round tubular housing, and the window enclosure surrounds an edge of the monitoring window in a rectangular configuration.

4. A pipeline monitoring assembly as claimed in claim 2 wherein the monitoring formation is mounted on the cover flap and the edge of the cover flap is provided with a flap which is fitted over the outside of the window shroud when the cover flap is snapped on.

5. A pipeline monitoring assembly as claimed in claim 4 wherein the cover flap is releasably connected to the window shroud.

6. The monitoring assembly for the conveying pipeline according to claim 5, wherein the window enclosing plate is provided with a first bolt hole, the cover plate turning edge is provided with a second bolt hole, and a connecting bolt penetrates through the first bolt hole and the second bolt hole.

7. The monitoring assembly of claim 1, wherein the guide plate is inclined inwardly in the feeding direction of the conveying passage, and the monitoring structure is higher than or flush with the bottom edge of the guide plate.

8. The monitoring assembly of a conveying pipeline according to claim 7, wherein the angle between the material guide plate and the axis of the conveying channel is any angle between 5 ° and 45 °.

9. A monitoring assembly for a conveying pipeline according to claim 1, wherein the monitoring structure includes a camera and a sensor, the camera having a camera shooting direction corresponding to the feeding direction of the conveying passage.

10. The monitoring assembly of claim 9, wherein the sensor is at least one of a pressure sensor, a flow sensor, a temperature sensor, and a humidity sensor.

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