CN216767463U - Pressurized pipeline conveying system - Google Patents

Pressurized pipeline conveying system Download PDF

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CN216767463U
CN216767463U CN202220369813.8U CN202220369813U CN216767463U CN 216767463 U CN216767463 U CN 216767463U CN 202220369813 U CN202220369813 U CN 202220369813U CN 216767463 U CN216767463 U CN 216767463U
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valve
conveying
way direction
pipe
continuous feeding
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吴学民
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Jincheng Mine Engineering Design Institute Co ltd
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Jincheng Mine Engineering Design Institute Co ltd
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Abstract

The utility model relates to a pressurized pipeline conveying system, which comprises a continuous feeding device and a conveying pipe, wherein the continuous feeding device comprises a rubbing and feeding device, a pressurized conveying pump and a discharging pipe, a check valve is arranged at a feeding port of the rubbing and feeding device, the check valve is connected with a discharging port of the upstream feeding device, a discharging port of the rubbing and feeding device is communicated with a feeding port of the pressurized conveying pump, a discharging port of the pressurized conveying pump is connected with the discharging pipe, a pulse current stabilizer for stabilizing fluid pulsation impact generated during the working of the conveying pump and stabilizing fluid flow is arranged on the discharging pipe, the discharging pipe is connected with the conveying pipe, and a check valve and a pressure sensor are arranged on the conveying pipe. The advantages are that: the pump body can effectively rub and break up materials and prepare fluidized paste fluid, so that good fluidity of the materials in the pipeline is maintained, meanwhile, the pipeline conveying is conveniently cut off for maintenance, the fluid pulsation impact generated in the pump body conveying process can be effectively reduced, and the safety of the conveying belt is improved.

Description

Pressurized pipeline conveying system
Technical Field
The utility model relates to the technical field of pipeline transportation of fluid media such as mine filling and the like, in particular to a pressurized pipeline transportation system.
Background
In the field of mine filling engineering, as the goaf to be filled has a plurality of wide areas, a conveying system is required to fill a plurality of goafs which are located at different points and need to be filled by a filling station integrating functions of tailing dehydration, filling slurry preparation, filling slurry pressurization conveying and the like according to mining and filling requirements.
Because the goaf area of a general mining area is wide and has many points, a pressurizing and conveying pump with enough pumping pressure is needed to carry out long-distance high-pressure conveying on filling slurry. Most of the pumps capable of realizing the long-distance high-pressure conveying function are volume type piston pumps or plunger pumps.
Since the displacement-type piston pump or plunger pump is characterized by sucking and pumping material according to the volume change of the pump cavity, the volume change inevitably causes the flow rate change of the conveyed material, and the flow rate change causes the generation of the pulsation impact phenomenon. The presence of such pulsating impacts can lead to increased wear on the inner walls of the transfer ducts and also to severe vibrations of the ducts which can lead to rapid failure of the connections and seals of the ducts. The pulse current stabilizer of the utility model is a device for reducing flow pulse generated by a volumetric delivery pump, stabilizing liquid flow and reducing pipeline vibration caused by the flow pulse.
In addition, in the field of mine filling engineering, various pipeline laying modes such as upward conveying, upward-downward conveying, multi-stage upward-downward and downward conveying and the like can be realized by a pump station according to the terrain conditions. The check valve is a device for preventing material from flowing back at the moment when the conveying pump is reversed and does not pump when the material is conveyed upwards.
In addition, during transportation, failures such as pipe burst, leakage, pipe blockage and the like may occur in the operation condition of a long-distance pipeline, and therefore, it is necessary to effectively monitor fluid information including pressure and the like in the pipeline so as to reduce safety accidents.
SUMMERY OF THE UTILITY MODEL
The utility model aims to provide a medical self-service terminal machine, which effectively overcomes the defects of the prior art.
The technical scheme for solving the technical problems is as follows:
the utility model provides a pressurization pipeline conveying system, including continuous feed equipment and conveyer pipe, above-mentioned continuous feed equipment is including rubbing with the hands and feeding device, pressurization delivery pump and discharging pipe, the above-mentioned feed inlet of rubbing with the hands and feeding device installs the check valve, the discharge gate of upper reaches feeding equipment is connected to above-mentioned check valve, the above-mentioned discharge gate of rubbing with the hands and feeding device communicates the feed inlet of above-mentioned pressurization delivery pump, the discharging pipe is connected to the discharge gate of above-mentioned pressurization delivery pump, and be equipped with on this discharging pipe and be used for stabilizing the fluid pulsation impact that the delivery pump during operation produced and make the steady pulse current stabilizer of liquid stream, above-mentioned conveyer pipe is connected to above-mentioned discharging pipe, be equipped with check valve and pressure sensor on the above-mentioned conveyer pipe.
On the basis of the technical scheme, the utility model can be further improved as follows.
Further, the continuous feeding devices are provided with at least three continuous feeding devices which are arranged in a row, wherein in three adjacent continuous feeding devices, three-way direction-changing valves I are respectively arranged at the discharge ends of the three continuous feeding devices in a one-to-one correspondence manner, each three-way direction-changing valve I is provided with a flow-combining port and two flow-dividing ports, and the discharge pipe of one continuous feeding device positioned in the middle is connected with the confluence port of the three-way direction-changing valve I corresponding to the discharge pipe, the discharge pipes of two continuous feeding devices positioned on two sides are respectively connected with the shunting ports of the three-way direction-changing valves I corresponding to the discharge pipes, the rest shunting ports of the two three-way direction-changing valves I positioned on two sides are respectively connected with the two shunting ports of the three-way direction-changing valve I positioned in the middle in a one-to-one correspondence manner, and the confluence ports of the two three-way direction-changing valves I positioned on two sides are respectively connected with one conveying pipe in a one-to-one correspondence manner.
Furthermore, the continuous feeding equipment is provided with two continuous feeding equipment, the discharge pipes of the two continuous feeding equipment are jointly provided with a three-way direction changing valve II, the three-way direction changing valve II is provided with a confluence port and two branch ports, the two branch ports of the three-way direction changing valve II are respectively connected with the discharge pipes of the two continuous feeding equipment in a one-to-one correspondence mode, and the confluence port of the three-way direction changing valve II is connected with the conveying pipe.
Furthermore, the continuous feeding equipment is provided with one tee bend valve III, the tee bend valve III is provided with a confluence opening and two branch openings, a discharge pipe of the continuous feeding equipment is connected with the confluence opening of the tee bend valve III through the conveying pipe, and the two branch openings of the tee bend valve III are respectively connected with branch pipes.
Furthermore, any one of the branch pipelines is provided with a three-way direction-changing valve IV, the three-way direction-changing valve IV is provided with a confluence port and two branch ports, the confluence port of the three-way direction-changing valve IV is connected with the corresponding branch pipeline, and the two branch ports of the three-way direction-changing valve IV are respectively connected with the sub pipelines.
Further, at least two continuous feeding devices are arranged in parallel in a row, the discharge pipe of each continuous feeding device is communicated with one conveying pipe in a one-to-one correspondence mode, two three-way direction changing valves V are arranged on the upstream and downstream of the conveying pipe corresponding to any one continuous feeding device at intervals, each three-way direction changing valve V is provided with a flow combining port and two flow dividing ports, the flow combining ports and the flow dividing ports of the three-way direction changing valves V are communicated with the corresponding pipelines respectively, and the remaining flow dividing ports of the two three-way direction changing valves V on the conveying pipe corresponding to any one continuous feeding device are connected with the remaining flow dividing ports of the two three-way direction changing valves V on the conveying pipe corresponding to the adjacent feeding device in a one-to-one correspondence mode.
Further, the pressure feed pump is a positive displacement piston pump or a plunger pump.
The utility model has the beneficial effects that: the pump body can effectively rub and break up materials and prepare fluidized paste fluid, so that good fluidity of the materials in the pipeline is maintained, meanwhile, the pipeline conveying is conveniently cut off for maintenance, the fluid pulsation impact generated in the pump body conveying process can be effectively reduced, and the safety of the conveying belt is improved.
Drawings
FIG. 1 is a first schematic view of a pressurized pipeline delivery system of the present invention in actual use;
FIG. 2 is a second schematic view of the pressurized pipeline transportation system of the present invention in actual use;
FIG. 3 is a third schematic view of the pressurized pipeline delivery system of the present invention in actual use;
FIG. 4 is a fourth schematic view of the pressurized tubular transport system of the present invention in actual use;
FIG. 5 is a fifth schematic view of the pressurized tubular transport system of the present invention in actual use;
fig. 6 is a schematic structural view of a three-way change-over valve in the pressurized piping system of the present invention.
In the drawings, the components represented by the respective reference numerals are listed below:
1. a continuous feeding device; 2. a delivery pipe; 4. a pulse current stabilizer; 6. a check valve; 7. a pressure sensor; 11. a kneading and feeding device; 12. a pressurized delivery pump; 13. a check valve; 101. a three-way direction-changing valve I; 102. a three-way direction changing valve II; 103. a three-way direction changing valve III; 104. a three-way direction changing valve IV; 105. and a three-way redirection valve V.
Detailed Description
The principles and features of this invention are described below in conjunction with the following drawings, which are set forth by way of illustration only and are not intended to limit the scope of the utility model.
Example (b): as shown in fig. 1 to 5, the pressurized pipeline conveying system of the present embodiment includes a continuous feeding device 1 and a conveying pipe 2, the continuous feeding device 1 includes a kneading and feeding device 11, a pressurized conveying pump 12 and a discharging pipe, a check valve 13 is installed at a feeding port of the kneading and feeding device 11, the check valve 13 is connected to a discharging port of an upstream feeding device, the discharging port of the kneading and feeding device 11 is communicated with the feeding port of the pressurized conveying pump 12, the discharging port of the pressurized conveying pump 12 is connected to the discharging pipe, a pulse current stabilizer 4 for stabilizing a fluid pulsation impact generated during the operation of the conveying pump and stabilizing a fluid flow is provided on the discharging pipe, the discharging pipe is connected to the conveying pipe 2, and a check valve 6 and a pressure sensor 7 are provided on the conveying pipe 2.
The functions and roles of the functional units of the present embodiment are as follows:
the check valve 13: the materials for conducting, controlling and isolating the upstream feeding process system enter the whole pressurized pipeline conveying system. In this embodiment, the stop valve 13 is a valve body described in patent application No. 2021203720565, and in a specific use process, the stroke of a valve plate of the stop valve 13 is controlled by a driving device, so that effective conduction is realized during normal conveying; when the low-flow conveying is carried out, effective flow control or throttling can be realized so as to control the feeding amount of an upstream feeding process system; when equipment fails, materials in an upstream feeding process unit can be isolated so as to facilitate maintenance and repair of downstream process equipment, and other references are not repeated herein.
The kneading and feeding device 11: for crushing, kneading and pressure feeding of the conveyed material. In this embodiment, a "paste pump feeding device" having a patent number of ZL201310235626.6 is preferably used. The structural principle of the feeding device of the paste pump is described in relevant documents. The paste pump feeding device preferably adopted by the utility model can break up, rub and crush the materials, and meanwhile, the two built-in reverse helical blades push the materials, so that the pressure borne by the materials is increased, and the materials are pressed into the feeding port of the pressure delivery pump 12 at a certain pressure, thereby solving the problem that the pressure delivery pump 12 is difficult to suck the materials, and ensuring that the pressure delivery pump 12 has good volumetric efficiency
Pressure delivery pump 12: the pressurizing pipeline conveying system is used for pressurizing and conveying materials, and in the embodiment, the pressurizing pipeline conveying system preferably adopts a positive displacement piston pump or a plunger pump due to the characteristic that the positive displacement piston pump or the plunger pump can generate high pressure. Specifically, "a spool valve hydraulic slurry pump" described in document CN202020477997.0, "a spool valve and a slurry pump including the spool valve" described in document CN202020477139.6, "an automatic cone valve and a slurry pump including the automatic cone valve" described in document CN202020477065.6, "a valve hydraulic slurry delivery pump" described in document CN202020477141.3, and "a pipe delivery system" described in document CN201920750944.9 are preferably used. The specific structure and principle of the above embodiments in the above documents are detailed in the related documents, and are not described herein. Since the pressurized delivery pump 12 according to the preferred embodiment has different structural and performance characteristics, it is selected in practical engineering according to the specific characteristics of the fluid to be delivered, so as to achieve the best pumping effect.
The pulse current stabilizer 4: the pump is used for stabilizing the impulse impact of fluid generated when the delivery pump works and enabling the liquid flow to be stable, specifically, in the process of reversing a plunger or a piston of the pressurizing delivery pump 12, the change of the delivery flow can be caused by the change of the volume of a pump cavity, the change can generate larger flow impulse under the action of the pump pressure, the flow impulse with larger kinetic energy acts on the outlet end of the pump and a subsequent pipeline to generate vibration, and the connection of the pipeline can be failed when the vibration is serious; the reaction force formed in the pipeline by the pulse impact can also cause adverse effect on the service life of the valve cavity of the delivery pump, and even the unstable pulse impact can also aggravate the erosion of materials to the pipeline, so that the design of the pulse current stabilizer 4 can well absorb and release pulse kinetic energy to stabilize the fluid pulse impact generated by the delivery pump; the pulse flow stabilizer 4 involved in the pressurized piping system in the present embodiment preferably employs a "paste pumping flow stabilizer" described in document zl201220691196.x, a "regulation type fluid pulsation damper" described in document CN201720106649.0, and a "flow stabilizer for a volumetric fluid apparatus" described in patent application No. 202022040923.3. The three technical products act on the floating piston through the fluid with pulse, and absorb and release the pulse kinetic energy through the elastic damping body to stabilize the fluid pulse impact generated by the delivery pump. The specific structure and principle of the above embodiments in the above documents are detailed in the related documents, and are not described herein.
A check valve 6: the device is used for preventing impact damage to the system caused by material backflow with high potential difference potential energy at the moment of reversing the pressurizing delivery pump 12.
The pressure sensor 7: the pressure measuring device is used for measuring the pressure condition in the conveying pipeline in real time and providing a judgment basis for judging the operation and fault conditions of the pipeline. In this embodiment, the pressure sensor 7 is a "flow-through paste pressure sensing device" described in the document ZL 201210542458.0. The diaphragm sleeve 714 of this type of pressure sensor 7 conforms to the inner diameter of the conduit 8 and does not create resistance to fluid flow; the problem of inaccurate measurement caused by the fact that materials easily enter the pressure guide hole to cause the blockage of the pressure guide hole or the metal diaphragm of the pressure transmitter 712 is easily abraded in the conventional measurement is solved. The pressure sensor 7 has a pressure signal remote transmission function, so that the actually measured pressure signal can be transmitted to a central control room of the conveying system, and the abnormal operation states such as pipe blockage, leakage, pipe explosion and the like can be alarmed currently according to the change of the pressure, so that the timely disposal is facilitated.
What needs to be supplemented is: in the embodiment, the pressure sensor 7 and the pressurizing delivery pump 12 are electrically connected with a remote central monitoring system through a power cable and a signal cable respectively and are subjected to remote central monitoring. Specifically, the remote central monitoring system mainly comprises an upper computer, a PLC programmable logic controller and a control cabinet, and these constituent units are common devices of an industrial automation control system and are not described in detail herein. The execution mechanism and the driving device for acquiring and controlling the operation state information of each functional unit in the embodiment are common control technologies and equipment in industry, and the embodiment is not specifically described.
What needs to be added specifically is: for the homogeneous slurry fluid with better fluidity, the pressurized pipeline conveying system of the embodiment does not need to be configured necessarily, for example, for the pressurized pipeline conveying of the homogeneous slurry fluid with better fluidity, the material twisting and feeding device 11 is not needed; when materials are conveyed downwards from the installation base surface of the pressure conveying pump 12, the materials do not flow back under the working condition, and the process unit and equipment for preventing the materials from flowing back can be realized without arranging the check valve 6.
In practical use, the system of the embodiment can be combined into at least the following various forms by adding three-way direction change valves according to different use requirements and working conditions:
1) as shown in figure 1, the continuous feeding equipment 1 is provided with at least three parts which are arranged in a row, wherein in three adjacent continuous feeding equipment 1, three-way direction-changing valves I101 are respectively arranged at the discharge ends of the three continuous feeding equipment 1 in a one-to-one correspondence manner, each three-way direction-changing valve I101 is provided with a flow-combining port and two diversion ports, the discharge pipe of the middle continuous feeding equipment 1 is connected with the flow-combining port of the three-way direction-changing valve I101 corresponding to the middle continuous feeding equipment, the discharge pipes of the two continuous feeding equipment 1 at two sides are respectively connected with the diversion ports of the three-way direction-changing valve I101 corresponding to the two discharge pipes, the rest diversion ports of the two three-way direction-changing valves I101 at two sides are respectively connected with the two diversion ports of the three-way direction-changing valve I101 at the middle in a one-to one correspondence manner, the confluence ports of the two three-way direction-changing valves I101 positioned at the two sides are respectively connected with the conveying pipes 2 in a one-to-one correspondence manner; in this scheme, arbitrary pressurization delivery pump 12 breaks down, through the switching of tee bend turn-over valve I101, still can guarantee normally to realize effectual transport to two conveyer pipes 2.
2) As shown in FIG. 2, the continuous feeding equipment 1 is provided with two pipes, the discharge pipes of the two continuous feeding equipment 1 are commonly provided with a three-way change-over valve II 102, the three-way change-over valve II 102 is provided with a confluence port and two branch ports, the two branch ports of the three-way change-over valve II 102 are respectively connected with the discharge pipes of the two continuous feeding equipment 1 in a one-to-one correspondence manner, and the confluence port is connected with the conveying pipe 2. In the scheme, when any one pressurizing conveying pump 12 breaks down, effective conveying to the conveying pipe 2 can be still ensured to be normally realized through switching of the three-way change valve II 102
3) As shown in fig. 3, the continuous feeding equipment 1 is provided with one and is provided with a three-way direction changing valve iii 103, the three-way direction changing valve iii 103 has a confluence port and two branch ports, the discharge pipe of the continuous feeding equipment 1 is connected with the confluence port of the three-way direction changing valve iii 103 through the conveying pipe 2, and the two branch ports of the three-way direction changing valve iii 103 are respectively connected with branch pipes. In this embodiment, one pressure feed pump 12 can realize effective feeding to any one of the two branch pipes by switching the three-way change-over valve iii 103 as needed.
4) On the basis of the scheme 3), as shown in fig. 4, a three-way redirecting valve iv 104 is arranged on any one of the branch pipelines, the three-way redirecting valve iv 104 has a confluence port and two branch ports, the confluence port of the three-way redirecting valve iv 104 is connected with the corresponding branch pipeline, and the two branch ports are respectively connected with the sub-pipelines. Any one of more than two main pipelines can be effectively conveyed through the redirection of the three-way redirection valve IV 104.
5) The "dual-purpose mutually-equipped" pressurized piping system, as shown in fig. 5, the above-mentioned continuous feeding apparatus 1 is provided with at least two, and are arranged in a row in parallel, the discharging pipes of each continuous feeding device 1 are communicated with one conveying pipe 2 in a one-to-one correspondence way, two three-way direction-changing valves V105 are respectively arranged at intervals at the upstream and downstream of the conveying pipe 2 corresponding to any one continuous feeding device 1, the three-way direction-changing valves V105 are respectively provided with a flow-combining port and two flow-dividing ports, and the merging port and one diversion port of the three-way redirection valve V105 are respectively communicated on corresponding pipelines, and the rest diversion ports of the two three-way redirection valves V105 on the conveying pipe 2 corresponding to any one continuous feeding device 1 are respectively connected with the rest diversion ports of the two three-way redirection valves V105 on the conveying pipe 2 corresponding to the adjacent continuous feeding device 1 in a one-to-one correspondence manner. The two pressurizing and conveying pumps 12 can simultaneously convey the two corresponding conveying pipes 2; by switching the four three-way change-over valves v 105, it is also possible to realize that any one of the pressure feed pumps 12 feeds any one of the feed pipes 2.
In connection with schemes 1) -5), it is additionally stated that: the above solutions only show several embodiments of the pipeline switching by the three-way reversing valve 5, and further embodiments can be derived according to engineering requirements and the gist of the present invention. All embodiments derived from the spirit of the utility model are within the scope of the utility model. In particular, as shown in the embodiments of fig. 1 to 5, the three-way directional valve can be installed in a forward direction or a reverse direction (i.e. the connection between the merging port and the branch port and the pipeline can be exchanged, and the material can be fed from the merging port, discharged from the branch port, or fed from the branch port and discharged from the merging port).
In this embodiment, all the involved three-way direction-changing valves (three-way direction-changing valve i 101, three-way direction-changing valve ii 102, three-way direction-changing valve iii 103, three-way direction-changing valve iv 104, and three-way direction-changing valve v 105) may adopt two-position three-way electromagnetic valves existing in the market, and are connected to the control system in this embodiment, or adopt the following valve body structures:
as shown in fig. 6, the three-way direction changing valve 3 includes a valve seat 31, a valve body 32 and a driving mechanism 33, the valve seat 31 is hollow, one side of the valve seat is provided with a confluence pipe hole, and the other side is provided with two shunt pipe holes side by side; the valve body 32 is hermetically assembled in the valve seat 31, and has two fluid passages 321 which are arranged side by side and penetrate through both sides thereof, the two fluid passages 321 are distributed in a fork shape, and one ends of the two fluid passages 321 close to the confluence pipe hole are close to each other, and the other ends are far away from each other, the valve body 32 can translate along both ends of the valve seat 31, and move to the state that both end ports of the two fluid passages 321 respectively penetrate through the confluence pipe hole and the two shunt pipe holes in a one-to-one correspondence manner; the driving mechanism 33 is assembled on the valve seat 31 and extends into the valve seat 31 to be connected with the valve body 32, and the driving mechanism 33 is used for driving the valve body 32 to translate along the valve seat 31 towards two ends thereof. Wherein the valve seat 31 comprises a single-hole valve plate 311 and a double-hole valve plate 312 which are arranged in parallel, the control of the single-hole valve plate 311 constitutes the confluence pipe hole, the two holes of the double-hole valve plate 312 constitute the shunt pipe holes, equidistant pipes 313 perpendicular to the single-hole valve plate 311 and the double-hole valve plate 312 are respectively supported and connected between the two sides of the two valve plates at intervals, the two sides of the single-hole valve plate 311 and the two-hole valve plate 312 are respectively fixed by bolts, structural end plates 314 are respectively connected between both ends of the single-hole valve plate 311 and the double-hole valve plate 312, the drive mechanism 33 is mounted on one of the structural end plates 314, both sides of the valve body 32 are in sealing contact with the single-hole valve plate 311 and the double-hole valve plate 312, the surfaces of the single-hole valve plate 311 and the double-hole valve plate 312 facing away from each other are respectively provided with pipe flanges 315 at the outlet of the confluence pipe hole and the outlet of the distribution pipe hole in a sealing manner. The two (channel) fluid passages 321 in the valve body 32 are integrally distributed in a fork shape, the fluid passages 321 in the valve body 32 adopt 'V' -shaped flow channels with large curvature radius structures, the flow channels are smooth and have no dead angles, so that the fluid resistance can be effectively reduced, the phenomenon of hardening retardation of materials in the flow channels is eliminated, the fluid resistance of the flow channels is effectively reduced, the whole switching valve can be applied to a high-pressure pipeline conveying system to realize the redirection conveying of one main pipeline to branch pipelines, and the redirection conveying of different branch pipelines to the main pipeline can be realized.
The surfaces of the single-hole valve plate 311 and the double-hole valve plate 312, which are respectively combined with the valve body 32, are respectively provided with guide chutes extending toward both ends thereof, both sides of the valve body 32 are respectively provided with sealing end plates 322, the sealing end plates 322 at both sides are respectively embedded in the guide chutes of the single-hole valve plate 311 and the double-hole valve plate 312 and can move toward both ends thereof along the guide chutes, the sealing end plates 322 at both sides are respectively provided with annular sealing grooves (denoted by a in the drawing) around both end ports of the two fluid passages 321, and the combination sealing ring 34 is embedded in the sealing grooves, thereby achieving the sealing between the sealing end plates 322 and the single-hole valve plate 311 or the double-hole valve plate 312.
Meanwhile, the driving mechanism 33 includes a hydraulic cylinder, a cylinder body of the hydraulic cylinder is assembled at any end of the valve seat 31, a connecting lug 323 is arranged at any end or two ends of the valve body 32, a piston rod of the hydraulic cylinder penetrates through the corresponding end of the valve seat 31, the end of the piston rod extends into the connecting lug 323 and is connected with the connecting lug 323 through a pin shaft, an oil path of the hydraulic cylinder is connected with a hydraulic station, and a control system is connected with an electromagnetic valve of the hydraulic station to realize oil path control of the driving mechanism 33, that is, realize reversing of the three-way change valve 3.
In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the utility model and to simplify the description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and are therefore not to be considered limiting of the utility model.
Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.
In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.
In the present invention, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may be directly contacting the second feature or the first and second features may be indirectly contacting each other through intervening media. Also, a first feature "on," "above," and "over" a second feature may be directly on or obliquely above the second feature, or simply mean that the first feature is at a higher level than the second feature. A first feature "under," "beneath," and "under" a second feature may be directly under or obliquely under the second feature, or may simply mean that the first feature is at a lesser elevation than the second feature.
In the description of the specification, reference to the description of "one embodiment," "some embodiments," "an example," "a specific example," or "some examples" or the like means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.
Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art within the scope of the present invention.

Claims (7)

1. A pressurized pipeline conveying system characterized by: including continuous feed equipment (1) and conveyer pipe (2), continuous feed equipment (1) is including rubbing with the hands with feeding device (11), pressurization delivery pump (12) and discharging pipe, rub with the hands with the feed inlet of feeding device (11) and install only logical valve (13), only logical valve (13) connect the discharge gate of upper reaches feeding equipment, rub with the hands discharge gate intercommunication with feeding device (11) the feed inlet of pressurization delivery pump (12), the discharging pipe is connected to the discharge gate of pressurization delivery pump (12), and is equipped with on this discharging pipe and is used for stabilizing the fluid pulsation impact that the delivery pump during operation produced and makes steady pulse current stabilizer (4) of liquid stream, the discharging pipe is connected conveyer pipe (2), be equipped with check valve (6) and pressure sensor (7) on conveyer pipe (2).
2. A pressurized pipeline delivery system according to claim 1, wherein: the continuous feeding equipment (1) is provided with at least three continuous feeding equipment (1) which are arranged in a row, wherein three adjacent continuous feeding equipment (1) are respectively provided with three-way direction-changing valves I (101) at the discharge ends of the three continuous feeding equipment (1) in a one-to-one correspondence manner, the three-way direction-changing valves I (101) are respectively provided with a flow-combining port and two branch ports, the discharge pipe of the continuous feeding equipment (1) positioned in the middle is connected with the flow-combining port of the three-way direction-changing valve I (101) corresponding to the discharge pipe, the discharge pipes of the two continuous feeding equipment (1) positioned in two sides are respectively connected with the branch ports of the three-way direction-changing valve I (101) corresponding to the discharge pipe, the rest branch ports of the two three-way direction-changing valves I (101) positioned in two sides are respectively connected with the two branch ports of the three-way direction-changing valve I (101) positioned in the middle in a one-to one correspondence manner, the confluence ports of the two three-way direction-changing valves I (101) on the two sides are respectively connected with the conveying pipes (2) in a one-to-one correspondence mode.
3. A pressurized pipeline delivery system according to claim 1, wherein: the continuous feeding equipment (1) is provided with two discharging pipes, the discharging pipes of the two continuous feeding equipment (1) are jointly provided with a three-way direction changing valve II (102), the three-way direction changing valve II (102) is provided with a confluence port and two branch ports, the two branch ports of the three-way direction changing valve II (102) are respectively connected with the discharging pipes of the two continuous feeding equipment (1) in a one-to-one correspondence mode, and the confluence port is connected with the conveying pipe (2).
4. A pressurized pipeline delivery system according to claim 1, wherein: the continuous feeding equipment (1) is provided with one tee bend valve III (103), the tee bend valve III (103) is provided with a confluence port and two branch ports, a discharge pipe of the continuous feeding equipment (1) is connected with the confluence port of the tee bend valve III (103) through the conveying pipe (2), and the two branch ports of the tee bend valve III (103) are respectively connected with branch pipes.
5. A pressurised pipeline delivery system as claimed in claim 4, wherein: any one branch pipeline is provided with a three-way direction-changing valve IV (104), the three-way direction-changing valve IV (104) is provided with a confluence port and two branch ports, the confluence port of the three-way direction-changing valve IV (104) is connected with the corresponding branch pipeline, and the two branch ports are respectively connected with sub pipelines.
6. A pressurized pipeline delivery system according to claim 1, wherein: the continuous feeding equipment (1) is provided with at least two continuous feeding equipment which are arranged in parallel in a row, the discharge pipe of each continuous feeding equipment (1) is communicated with one conveying pipe (2) in a one-to-one correspondence manner, the upstream and downstream of the conveying pipe (2) corresponding to any one continuous feeding equipment (1) are respectively provided with two three-way direction-changing valves V (105) at intervals, the three-way direction-changing valves V (105) are respectively provided with a flow closing port and two flow dividing ports, and the merging opening and one shunting opening of the three-way direction-changing valve V (105) are respectively communicated on corresponding pipelines, and the rest shunting openings of the two three-way direction-changing valves V (105) on the conveying pipe (2) corresponding to any one continuous feeding equipment (1) are respectively connected with the rest shunting openings of the two three-way direction-changing valves V (105) on the conveying pipe (2) corresponding to the adjacent feeding equipment (1) in a one-to-one correspondence manner.
7. A pressurised pipeline delivery system as claimed in any one of claims 1 to 6, wherein: the pressurizing and conveying pump (12) is a positive displacement piston pump or a plunger pump.
CN202220369813.8U 2022-02-23 2022-02-23 Pressurized pipeline conveying system Active CN216767463U (en)

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Application Number Priority Date Filing Date Title
CN202220369813.8U CN216767463U (en) 2022-02-23 2022-02-23 Pressurized pipeline conveying system

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202220369813.8U CN216767463U (en) 2022-02-23 2022-02-23 Pressurized pipeline conveying system

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CN216767463U true CN216767463U (en) 2022-06-17

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Country Link
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