Multi-functional pipeline device of row mixes
Technical Field
The utility model relates to an oil drilling equipment field, especially a mix and arrange multi-functional piping installation.
Background
In the field of oil and natural gas production, a mixed arrangement device is core equipment in fracturing construction, and the existing mixed arrangement device mostly adopts a single-line production system, namely, one mixed arrangement device is provided with a manifold, and when one manifold goes wrong, or one mixed arrangement device goes wrong, the whole line cannot be used. For example, the Chinese patent document CN103343679B is an electro-hydraulic hybrid driven sand mixing truck, and CN103912259A is an electrically driven sand mixing truck which all have the problems.
SUMMERY OF THE UTILITY MODEL
The utility model aims to solve the technical problem that a mix and arrange multi-functional piping installation is provided, can still remain partial function when partial part breaks down to realize higher fault-tolerance, ensure the continuity of mixing and arranging the construction, the maintenance of the partial equipment of also being convenient for.
In order to solve the technical problem, the utility model discloses the technical scheme who adopts is: the utility model provides a mix and arrange multi-functional pipe-line apparatus, includes that first row of inserting pipeline, first discharge port pipeline, second are mixed and are arranged inserting pipeline and second and mix the discharge port pipeline, is equipped with the connecting pipe between the export between first discharge port pipeline and the second of mixing and arrange the outlet pipe way, is equipped with the valve member on the connecting pipe between the export. In a preferred scheme, the valve part is an electric control or hydraulic control valve. The valve is a butterfly valve.
In a preferable scheme, valve members are arranged on the upstream and the downstream of the connecting position of the first mixed discharge outlet pipeline and the outlet connecting pipe;
and valves are arranged on the upstream and the downstream of the connecting position of the second mixed discharge outlet pipeline and the outlet connecting pipe.
In the preferred scheme, a first inlet-outlet connecting pipe is arranged between the first mixed drainage access pipeline and the first mixed drainage outlet pipeline, and a valve is arranged on the first inlet-outlet connecting pipe;
a second inlet and outlet connecting pipe is arranged between the second mixed drainage access pipeline and the second mixed drainage outlet pipeline, and a valve is arranged on the second inlet and outlet connecting pipe.
In a preferred scheme, valve elements are arranged on the upstream and the downstream of the connecting position of the first mixed drainage access pipeline and the first mixed drainage outlet pipeline and the first inlet and outlet connecting pipe;
and valve members are arranged on the upstream and the downstream of the connecting position of the second inlet and outlet connecting pipes on the second mixed drainage access pipeline and the second mixed drainage outlet pipeline.
In the preferred scheme, an inter-inlet connecting pipe is further arranged between the first mixed row access pipeline and the second mixed row access pipeline, and a valve is arranged on the inter-inlet connecting pipe.
In a preferable scheme, valve members are arranged on the upstream and the downstream of the connecting position of the first mixed row access pipeline and the second mixed row access pipeline and the connecting pipe between the inlets.
In the preferred scheme, the inlet connecting pipe, the first inlet-outlet connecting pipe and the second inlet-outlet connecting pipe which are arranged in parallel and the outlet connecting pipe are sequentially arranged from upstream to downstream.
In the preferred scheme, one end of a first mixed row access pipeline is connected with an outlet of a first liquid supply pump, and the other end of the first mixed row access pipeline is connected with a first mixed row device;
one end of the first mixing discharge port pipeline is connected with the first mixing discharge device;
one end of the second mixed row access pipeline is connected with an outlet of the second liquid supply pump, and the other end of the second mixed row access pipeline is connected with the second mixed row device;
one end of the second mixing discharge port pipeline is connected with the second mixing discharge device.
In a preferred scheme, pressure sensors are arranged on the first mixed discharge inlet pipeline, the first mixed discharge outlet pipeline, the second mixed discharge inlet pipeline and the second mixed discharge outlet pipeline.
In a preferred scheme, flow meters are arranged on the first mixing and discharging outlet pipeline and the second mixing and discharging outlet pipeline.
The utility model provides a pair of mix and arrange multi-functional pipe device can realize the work of multipath, for example, through operating corresponding valve member, can realize respectively that left side is inhaled the left row, left side is inhaled the right row, right side is inhaled the left row, one inhale double, double inhale one row, bypass manifold, do not inhale the flowing back mode through multiple such as mixing and arranging the device promptly, the well site of fracturing blender truck is connected and is put when being convenient for fracturing operation. And when one part of the components needs maintenance, the functions of other parts can be maintained, and the continuity of work can be ensured.
Drawings
The invention will be further explained with reference to the following figures and examples:
fig. 1 is a schematic top view of the present invention.
Fig. 2 is a schematic bottom view of the present invention.
Fig. 3 is a perspective view of the present invention.
Fig. 4 is a schematic view of the connection structure of the present invention.
In the figure: the device comprises a first mixed drainage access pipeline 1, a second mixed drainage access pipeline 2, a first mixed drainage outlet pipeline 3, a second mixed drainage outlet pipeline 4, an outlet connection pipe 5, a flowmeter 6, a valve 7, a first inlet and outlet connection pipe 8, a second inlet and outlet connection pipe 9, a first mixed drainage device 10, a second mixed drainage device 11, a first liquid supply pump 12, a second liquid supply pump 13, an inlet connection pipe 14 and a pressure sensor 15.
Detailed Description
As shown in fig. 1 to 4, a mixed-discharging multifunctional pipeline device includes a first mixed-discharging inlet pipeline 1, a first mixed-discharging outlet pipeline 3, a second mixed-discharging inlet pipeline 2, and a second mixed-discharging outlet pipeline 4, wherein an inter-outlet connecting pipe 5 is disposed between the first mixed-discharging outlet pipeline 3 and the second mixed-discharging outlet pipeline 4, and a valve member 7, such as a butterfly valve 707, is disposed on the inter-outlet connecting pipe 5. The valve is an electric control or hydraulic control valve. The valve element 7 in this example is preferably a butterfly valve. The electric control or hydraulic control butterfly valve is convenient for realizing automatic or remote switching operation. With the structure, when one outlet pipeline has a problem, the two mixed discharging devices can be switched to use one outlet pipeline, or different discharging directions can be switched.
In a preferred embodiment, as shown in fig. 4, a valve is disposed on the first mixing and discharging port pipe 3, upstream and downstream of the connection position of the first mixing and discharging port pipe 3 and the outlet connection pipe 5; such as butterfly valve 705 and butterfly valve 706 in fig. 4.
Valves are arranged on the second mixed discharge outlet pipeline 4 at the upstream and downstream of the connecting position of the second mixed discharge outlet pipeline 4 and the outlet connecting pipe 5. Such as butterfly valve 708, butterfly valve 709 in fig. 4. The direction of the discharge pipeline is switched by each butterfly valve.
In the preferred scheme as shown in fig. 1-4, a first inlet-outlet connecting pipe 8 is arranged between a first mixed-discharging access pipeline 1 and a first mixed-discharging outlet pipeline 3, and a valve is arranged on the first inlet-outlet connecting pipe 8; such as a butterfly valve 704.
A second inlet/outlet connecting pipe 9 is arranged between the second mixed discharge inlet pipeline 2 and the second mixed discharge outlet pipeline 4, and a valve element, such as a butterfly valve 710, is arranged on the second inlet/outlet connecting pipe 9. With the structure, the direction of the suction pipeline can be conveniently switched.
In the preferred scheme, valve members are arranged on the upstream and the downstream of the connecting position of the first mixed drainage access pipeline 1 and the first mixed drainage outlet pipeline 3 and the first inlet and outlet connecting pipe 8; such as butterfly valve 703, butterfly valve 706, butterfly valve 702, butterfly valve 705.
Valves, such as butterfly valves 708, 709, 711, and 712, are provided upstream and downstream of the connection point of the second inlet/outlet connection pipe 9 in the second mixing and discharging inlet pipe 2 and the second mixing and discharging outlet pipe 4.
In a preferred embodiment, an inter-inlet connection pipe 14 is further disposed between the first mixed row access pipe 1 and the second mixed row access pipe 2, and a valve element, such as a butterfly valve 714, is disposed on the inter-inlet connection pipe 14.
In a preferred scheme, valve elements are arranged on the upstream and the downstream of the connection position of the first mixed discharge access pipeline 1 and the second mixed discharge access pipeline 2 and the inlet connecting pipe 14. Such as butterfly valve 701, butterfly valve 702, butterfly valve 713, butterfly valve 712.
In a preferred embodiment, as shown in fig. 4, the inter-inlet connection pipe 14, the first inlet/outlet connection pipe 8 and the second inlet/outlet connection pipe 9 arranged in parallel, and the inter-outlet connection pipe 5 are arranged in this order from upstream to downstream. By the structure, switching of different paths is realized.
In a preferred scheme, as shown in fig. 1 to 4, one end of a first mixed drainage access pipeline 1 is connected with an outlet of a first liquid supply pump 12, and the other end of the first mixed drainage access pipeline 1 is connected with a first mixed drainage device 10;
one end of the first mixing and discharging port pipeline 3 is connected with a first mixing and discharging device 10;
one end of the second mixed-discharge access pipeline 2 is connected with an outlet of the second liquid supply pump 13, and the other end of the second mixed-discharge access pipeline 2 is connected with the second mixed-discharge device 11;
one end of the second mixing and discharging port pipeline 4 is connected with the second mixing and discharging device 11.
Through switching the valve elements, various working modes such as left suction left discharge, left suction right discharge, right suction left discharge, suction double discharge, double suction single discharge, bypass manifold and the like are respectively realized.
In a preferred embodiment, pressure sensors 15 are disposed on the first mixed row inlet pipeline 1, the first mixed row outlet pipeline 3, the second mixed row inlet pipeline 2 and the second mixed row outlet pipeline 4. According to the pressure value of pressure sensor 15 collection on the mixed drainage outlet pipeline, the output pressure of control feed pump and the sand feeding volume of mixing and arranging the device, set up the pressure value of gathering at the pressure sensor 15 that inserts the pipeline, the cooperation is adjusted inverter motor or hydraulic motor driven output pressure and the flow of first feed pump 12 and second feed pump 13, be convenient for control feed liquor flow, the sand feeding volume of control and first mixed arranging device 10 and second mixed arranging device 11 simultaneously, the control to sand feeding volume that needs to explain also has the effect of adjusting mixed arranging device output pressure, with under the stable prerequisite of proportion of guaranteeing to thoughtlessly mixing, keep output pressure stable.
In a preferred embodiment, as shown in fig. 2 and 4, flow meters 6 are provided in the first mixing outlet pipe 3 and the second mixing outlet pipe 4. Preferably, the flow meter 6 is an electromagnetic flow meter. The flowmeter 6 is also used for correcting an output pressure sensor of the mixed discharge port pipeline, and the flow value in the preset process corresponds to the preset output pressure value; when the corresponding relation is lost, the preset output pressure value is unchanged and the flow value is increased, the rotating speed of a driving device of the liquid supply pump is correspondingly increased, and a warning is sent to remind that the output pressure sensor is in failure; the output pressure value is unchanged and the flow value is reduced, so that the rotating speed of a driving device of the liquid supply pump is correspondingly reduced, and a warning is sent to remind that the output pressure sensor has faults.
The utility model discloses a control each valve member 7 and switch corresponding mode and realize online maintenance function. For example, when a certain mixing and discharging device is damaged and needs maintenance, the mixing and discharging device is disconnected and bypassed by the switching valve member 7, so that the mixing and discharging device can be maintained on line without shutdown.
The above-mentioned embodiments are merely preferred embodiments of the present invention, and should not be considered as limitations of the present invention, and the protection scope of the present invention should be defined by the technical solutions described in the claims, and includes equivalent alternatives of technical features in the technical solutions described in the claims. Namely, equivalent alterations and modifications within the scope of the invention are also within the scope of the invention. For the sake of brevity, all the combinations of the embodiments are not exemplified, and therefore, the technical features of the embodiments can be combined with each other to generate more technical solutions without conflict.