CN212396517U - High-temperature cross-linking agent system for fracturing - Google Patents

Abstract

The utility model discloses a high-temperature cross-linking agent system for fracturing, which comprises a mixing barrel and an anti-vibration base which are arranged from top to bottom; the lower end of the mixing cylinder is detachably and hermetically connected with the anti-vibration base, and a mixing auger which can rotate circumferentially and is vertically arranged is arranged in the mixing cylinder; the inner wall of the mixing cylinder is also provided with a spiral stirring blade which is spirally arranged from top to bottom, the spiral stirring blade and the mixing auger are in transmission connection with a driving assembly arranged in the mounting seat, and the rotation directions of the mixing auger and the spiral stirring blade are opposite. The utility model can efficiently mix the cross-linking agent; when in mixing, the rotation directions of the spiral stirring blades and the mixing auger are opposite; mixing from top to bottom and from inside to outside can be realized; the mixing operation is more time-saving and labor-saving, and the processing efficiency is obviously improved; the utility model provides an among the prior art shortcoming such as crosslinking agent mixing efficiency low, mixed quality is poor, the operation is inconvenient.

Description

High-temperature cross-linking agent system for fracturing

Technical Field

The utility model relates to a cross-linking agent technical field, concretely relates to high temperature cross-linking agent system for fracturing.

Background

The cross-linking agent is also called bridging agent, and is an important component of the polyhydrocarbon photoresist, and the photochemical curing action of the photoresist depends on the cross-linking agent with double photosensitive functional groups to participate in reaction, and after the cross-linking agent is exposed, the cross-linking agent generates double free radicals, which react with the polyhydrocarbon resin to form bridge bonds between polymer molecular chains and become insoluble substances with three-dimensional structures. The operation of the cross-linking agent requires the use of devices such as a mixer, an electronic balance, a measuring cylinder, a pipette, a beaker and the like, but the existing cross-linking agent mixer has some disadvantages, for example, the existing cross-linking agent mixer cannot mix the raw materials of the cross-linking agent well, and the operation is complicated, the stability is not strong, the mixing at different rotating speeds cannot be performed, and the practicability of the cross-linking agent mixer is seriously reduced.

SUMMERY OF THE UTILITY MODEL

To the defect among the prior art, the utility model aims to provide a high temperature cross-linking agent system for fracturing can improve quality and the efficiency that the cross-linking agent mixes.

The utility model adopts the technical proposal that: a high-temperature cross-linking agent system for fracturing comprises a mixing barrel and an anti-vibration base which are arranged from top to bottom; the lower end of the mixing cylinder is detachably and hermetically connected with an anti-vibration base, anti-vibration support columns which are horizontally arranged and extend to the upper end of the mixing cylinder are arranged on the anti-vibration base corresponding to the two horizontal sides of the mixing cylinder, and a mounting seat fixedly connected with the anti-vibration support columns is arranged at the upper end of the mixing cylinder; be equipped with in the compounding section of thick bamboo can circumferential direction and follow vertical arrangement's compounding auger, compounding section of thick bamboo inner wall still is equipped with the spiral stirring leaf that top-down spiral was arranged, spiral stirring leaf is connected and compounding auger and the drive assembly transmission of locating in the mount pad is opposite with spiral stirring leaf rotation direction with the compounding auger.

In the technical scheme; the cross-linking agent materials can be placed in a mixing barrel for efficient mixing; when the cross-linking agent material is input into the mixing cylinder, the mixing auger and the spiral stirring blade rotate simultaneously to realize full mixing; the rotation directions of the spiral stirring blades and the mixing auger are opposite; the spiral stirring blade can lift the cross-linking agent materials upwards when rotating, the cross-linking agent materials can fall from the upper end of the spiral stirring blade, and the mixing auger can further improve the mixing degree in the rotating process; mixing from top to bottom and from inside to outside is realized; the mixing operation is more time-saving and labor-saving, and the processing efficiency is obviously improved.

Preferably, the drive assembly is including locating the buncher in the mount pad, the output shaft of buncher passes through the gear train and is connected with spiral stirring leaf and compounding auger transmission, the buncher still has the control panel of locating on the anti vibration base through circuit connection.

Preferably, the upper end of the mounting seat is provided with a plurality of feed inlets, and the feed inlets are communicated with the inner cavity of the mixing barrel through feed pipes; be equipped with the feeding solenoid valve between feed inlet and the inlet pipe, the feeding solenoid valve is connected with control panel electricity.

Preferably, the upper end of the anti-vibration base is provided with a threaded mounting hole for mounting the mixing cylinder, the bottom wall of the threaded mounting hole is arranged in a conical shape, the side face of the anti-vibration base is provided with a discharge hole identical to the threaded mounting hole, the discharge hole is provided with a discharge electromagnetic valve for opening and closing the discharge hole, and the discharge electromagnetic valve is electrically connected with the control panel.

Preferably, the lower end of the mixing cylinder is provided with a sealing joint in threaded fit with the threaded mounting hole

Preferably, a pneumatic vibration damper is arranged in the vibration-proof support.

Preferably, the bottom surface of the anti-vibration base is provided with a plurality of shock-absorbing support pads.

Preferably, a vibrator for vibrating the mixing cylinder is arranged in the anti-vibration base.

The utility model has the advantages that: the high-temperature cross-linking agent system for fracturing can efficiently mix the cross-linking agent; when in mixing, the rotation directions of the spiral stirring blades and the mixing auger are opposite; mixing from top to bottom and from inside to outside can be realized; the mixing operation is more time-saving and labor-saving, and the processing efficiency is obviously improved; the utility model solves the defects of low mixing efficiency, poor mixing quality, inconvenient operation and the like of the cross-linking agent in the prior art; has higher practical and popularization value.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below. Throughout the drawings, like elements or portions are generally identified by like reference numerals. In the drawings, elements or portions are not necessarily drawn to scale.

Fig. 1 is a schematic structural diagram of a high-temperature crosslinking agent system for fracturing provided by an embodiment of the present invention.

Reference numerals: the vibration-proof type mixing device comprises an anti-vibration base 100, a vibration-absorption supporting pad 110, a threaded mounting port 120, a mixing barrel 200, a mixing auger 300, a spiral stirring blade 400, an anti-vibration support column 500, an air pressure vibration absorber 510, a mounting seat 600, a speed regulating motor 700, a gear set 800, a feeding port 900, a feeding electromagnetic valve 1000, a discharging electromagnetic valve 1100, a control panel 1300 and a vibrator 1200.

Detailed Description

Here, it is to be noted that the functions, methods, and the like related to the present invention are only conventional adaptive applications of the related art. Therefore, the present invention is an improvement of the prior art, which substantially lies in the connection relationship between hardware, not in the functions and methods themselves, that is, the present invention relates to a few functions and methods, but does not include the improvements proposed in the functions and methods themselves. The present invention is described for better illustration of the function and method for better understanding of the present invention.

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and therefore are only examples, and the protection scope of the present invention is not limited thereby.

It is to be noted that unless otherwise specified, technical or scientific terms used herein shall have the ordinary meaning as understood by those skilled in the art to which the present invention belongs.

As shown in fig. 1, the high-temperature crosslinking agent system for fracturing provided by this embodiment includes a mixing cylinder 200 and an anti-vibration base 100 arranged from top to bottom; the lower end of the mixing cylinder 200 is detachably and hermetically connected with the anti-vibration base 100, the anti-vibration base 100 is provided with anti-vibration support columns 500 which are horizontally arranged corresponding to the two horizontal sides of the mixing cylinder 200 and extend to the upper end of the mixing cylinder 200, and the upper end of the mixing cylinder 200 is provided with a mounting seat 600 fixedly connected with the anti-vibration support columns 500; be equipped with in the compounding section of thick bamboo 200 can circumferential direction and follow vertical arrangement's compounding auger 300, compounding section of thick bamboo 200 inner wall still is equipped with the spiral stirring leaf 400 that top-down spiral was arranged, spiral stirring leaf 400 is connected and compounding auger 300 and the drive assembly transmission of locating in mount pad 600 rotate opposite direction with spiral stirring leaf 400 with compounding auger 300. The cross-linking agent materials can be placed in the mixing barrel 200 for efficient mixing; when the cross-linking agent material is input into the mixing cylinder 200, the mixing auger 300 and the spiral stirring blade 400 rotate simultaneously to realize full mixing; the rotation directions of the spiral stirring blades 400 and the mixing auger 300 are opposite; the spiral stirring blade 400 can lift the cross-linking agent materials upwards when rotating, the cross-linking agent materials can fall from the upper end of the spiral stirring blade 400, and the mixing auger 300 can further improve the mixing degree in the rotating process; mixing from top to bottom and from inside to outside is realized; the mixing operation is more time-saving and labor-saving, and the processing efficiency is obviously improved.

As mentioned above, the spiral stirring blade and the mixing auger 300 are driven by the driving assembly to rotate, the driving assembly in this embodiment includes the speed regulating motor 700 arranged in the mounting base 600, the output shaft of the speed regulating motor 700 is in transmission connection with the spiral stirring blade 400 and the mixing auger 300 through the gear set 800, and the speed regulating motor 700 is further connected with the control panel 1300 arranged on the anti-vibration base 100 through the circuit. Therefore, when the speed regulating motor 700 rotates, the spiral stirring blade 400 and the material mixing auger 300 are driven to rotate through the transmission of the gear set 800, and because the spiral stirring blade 400 and the material mixing auger 300 need to rotate oppositely, two sets of the gear set 800 can be selected, one set is in transmission connection with the spiral stirring blade 400, and the other set is in transmission connection with the material mixing auger 300; in this embodiment, the adjustable speed motor 700 can be a dc adjustable speed motor 700 or an ac adjustable speed motor 700; the control panel 1300 for controlling the rotation of the speed regulating motor 700 preferably uses a PLC controller, and the control mode of the PLC controller is the existing control technology in the field of circuit control, and is not described herein again.

As shown in fig. 1, in order to facilitate the introduction of the cross-linking agent into the mixing cylinder 200, in this embodiment, a plurality of feed inlets 900 are provided at the upper end of the mounting base 600, and the feed inlets 900 are communicated with the inner cavity of the mixing cylinder 200 through feed pipes; be equipped with feeding solenoid valve 1000 between feed inlet 900 and the inlet pipe, feeding solenoid valve 1000 is connected with control panel 1300 electricity. The control panel 1300 can control the on-off of the feeding electromagnetic valve 1000, so as to realize the input of materials, and the feeding electromagnetic valve 1000 can select related specifications and models as required.

As shown in fig. 1, in order to facilitate mounting and dismounting the mixing cylinder 200, in this embodiment, a threaded mounting hole for mounting the mixing cylinder 200 is formed in the upper end of the anti-vibration base 100, the bottom wall of the threaded mounting hole 120 is arranged in a tapered shape, a discharge hole identical to the threaded mounting hole 120 is formed in the side surface of the anti-vibration base 100, the discharge hole is provided with a discharge electromagnetic valve for opening and closing the discharge hole, the discharge electromagnetic valve 1100 is electrically connected to the control panel 1300, and in addition, a sealing joint in threaded fit with the threaded mounting hole 120 is formed in the lower end of the mixing cylinder 200. The sealing joint of the mixing cylinder 200 can be arranged on the thread mounting port 120 in a thread mounting mode, so that the mounting stability of the mixing cylinder 200 is improved, and the mixed cross-linking agent can be output through the discharge port after the cross-linking agent is mixed.

As shown in fig. 1, since the driving assembly drives the spiral stirring blade 400 and the mixing auger 300 to rotate and generate a certain vibration, the vibration-proof support 500 for supporting the mounting base 600 in this embodiment is provided with a pneumatic vibration absorber 510. The pneumatic vibration absorber 510 has a vibration absorbing function, so that the vibration amplitude of the equipment can be reduced; further, the bottom surface of the vibration-proof base 100 is provided with a plurality of vibration-absorbing support pads 110. The shock-absorbing support pad 110 may improve the stability of the entire device.

As shown in FIG. 1, the materials may be further mixed by vibration mixing in the mixing mode, and in view of this, the present embodiment is provided with a vibrator 1200 for vibrating the mixing cylinder 200 in the vibration-proof base 100. The vibrator 1200 may be a motor vibrator 1200, and is connected to the control panel 1300 when being installed, so as to control the vibration time and the vibration intensity.

In the specification of the present invention, a large number of specific details are explained. It is understood, however, that embodiments of the invention may be practiced without these specific details. In some instances, well-known methods, systems, and techniques have not been shown in detail in order not to obscure an understanding of this description.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not substantially depart from the scope of the embodiments of the present invention, and are intended to be covered by the claims and the specification.

Claims (8)

1. A high-temperature cross-linking agent system for fracturing comprises a mixing barrel (200) and an anti-vibration base (100) which are arranged from top to bottom; the method is characterized in that:

the lower end of the mixing cylinder (200) is detachably and hermetically connected with an anti-vibration base (100), the anti-vibration base (100) is provided with anti-vibration support columns (500) which are horizontally arranged corresponding to the two horizontal sides of the mixing cylinder (200) and extend to the upper end of the mixing cylinder (200), and the upper end of the mixing cylinder (200) is provided with a mounting seat (600) fixedly connected with the anti-vibration support columns (500);

be equipped with in mixing cylinder (200) can circumferential direction and follow vertical arrangement's compounding auger (300), mixing cylinder (200) inner wall still is equipped with spiral stirring leaf (400) that top-down spiral was arranged, spiral stirring leaf (400) are connected and compounding auger (300) and spiral stirring leaf (400) rotation opposite direction with the drive assembly transmission of locating in mount pad (600) with compounding auger (300).

2. The high temperature crosslinker system for fracturing of claim 1, wherein: the drive assembly is including locating buncher (700) in mount pad (600), the output shaft of buncher (700) passes through gear train (800) and spiral stirring leaf (400) and compounding auger (300) transmission and is connected, buncher (700) still is connected with control panel (1300) of locating on anti vibration base (100) through the circuit.

3. The high temperature crosslinker system for fracturing of claim 2, wherein: the upper end of the mounting seat (600) is provided with a plurality of feed inlets (900), and the feed inlets (900) are communicated with the inner cavity of the mixing barrel (200) through feed pipes; be equipped with feeding solenoid valve (1000) between feed inlet (900) and the inlet pipe, feeding solenoid valve (1000) are connected with control panel (1300) electricity.

4. The high temperature crosslinker system for fracturing of claim 2, wherein: the anti-vibration mixing device is characterized in that a thread mounting opening (120) used for mounting the mixing cylinder (200) is formed in the upper end of the anti-vibration base (100), the bottom wall of the thread mounting opening (120) is arranged in a conical shape, a discharge hole identical to the thread mounting opening (120) is formed in the side face of the anti-vibration base (100), a discharge electromagnetic valve used for opening and closing the discharge hole is formed in the discharge hole, and the discharge electromagnetic valve (1100) is electrically connected with the control panel (1300).

5. The high temperature crosslinker system for fracturing of claim 4, wherein: and a sealing joint in threaded fit with the threaded mounting hole (120) is arranged at the lower end of the mixing cylinder (200).

6. The high temperature crosslinker system for fracturing of claim 1, wherein: an air pressure vibration damper (510) is arranged in the vibration-proof support column (500).

7. The high temperature crosslinker system for fracturing of claim 1, wherein: the bottom surface of the anti-vibration base (100) is provided with a plurality of shock-absorbing support pads (110).

8. The high temperature crosslinker system for fracturing of claim 1, wherein: and a vibrator (1200) for vibrating the mixing cylinder (200) is arranged in the anti-vibration base (100).

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