WO2013063809A1 - 卷扬式提拉采油系统及其抽油绳的制造方法 - Google Patents

卷扬式提拉采油系统及其抽油绳的制造方法 Download PDF

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Publication number
WO2013063809A1
WO2013063809A1 PCT/CN2011/081838 CN2011081838W WO2013063809A1 WO 2013063809 A1 WO2013063809 A1 WO 2013063809A1 CN 2011081838 W CN2011081838 W CN 2011081838W WO 2013063809 A1 WO2013063809 A1 WO 2013063809A1
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WO
WIPO (PCT)
Prior art keywords
oil
steel
rope
wire
extraction system
Prior art date
Application number
PCT/CN2011/081838
Other languages
English (en)
French (fr)
Inventor
杨朝杰
Original Assignee
大庆北研石油设备制造有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by 大庆北研石油设备制造有限公司 filed Critical 大庆北研石油设备制造有限公司
Priority to PCT/CN2011/081838 priority Critical patent/WO2013063809A1/zh
Publication of WO2013063809A1 publication Critical patent/WO2013063809A1/zh

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Classifications

    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B43/00Methods or apparatus for obtaining oil, gas, water, soluble or meltable materials or a slurry of minerals from wells
    • E21B43/12Methods or apparatus for controlling the flow of the obtained fluid to or in wells
    • E21B43/121Lifting well fluids
    • E21B43/126Adaptations of down-hole pump systems powered by drives outside the borehole, e.g. by a rotary or oscillating drive
    • DTEXTILES; PAPER
    • D07ROPES; CABLES OTHER THAN ELECTRIC
    • D07BROPES OR CABLES IN GENERAL
    • D07B1/00Constructional features of ropes or cables
    • D07B1/16Ropes or cables with an enveloping sheathing or inlays of rubber or plastics
    • D07B1/162Ropes or cables with an enveloping sheathing or inlays of rubber or plastics characterised by a plastic or rubber enveloping sheathing
    • DTEXTILES; PAPER
    • D07ROPES; CABLES OTHER THAN ELECTRIC
    • D07BROPES OR CABLES IN GENERAL
    • D07B1/00Constructional features of ropes or cables
    • D07B1/16Ropes or cables with an enveloping sheathing or inlays of rubber or plastics
    • D07B1/165Ropes or cables with an enveloping sheathing or inlays of rubber or plastics characterised by a plastic or rubber inlay
    • DTEXTILES; PAPER
    • D07ROPES; CABLES OTHER THAN ELECTRIC
    • D07BROPES OR CABLES IN GENERAL
    • D07B7/00Details of, or auxiliary devices incorporated in, rope- or cable-making machines; Auxiliary apparatus associated with such machines
    • D07B7/02Machine details; Auxiliary devices
    • D07B7/14Machine details; Auxiliary devices for coating or wrapping ropes, cables, or component strands thereof
    • D07B7/145Coating or filling-up interstices
    • DTEXTILES; PAPER
    • D07ROPES; CABLES OTHER THAN ELECTRIC
    • D07BROPES OR CABLES IN GENERAL
    • D07B2201/00Ropes or cables
    • D07B2201/20Rope or cable components
    • D07B2201/2083Jackets or coverings
    • D07B2201/2087Jackets or coverings being of the coated type
    • DTEXTILES; PAPER
    • D07ROPES; CABLES OTHER THAN ELECTRIC
    • D07BROPES OR CABLES IN GENERAL
    • D07B2201/00Ropes or cables
    • D07B2201/20Rope or cable components
    • D07B2201/2083Jackets or coverings
    • D07B2201/2088Jackets or coverings having multiple layers

Definitions

  • the present invention relates to an oil recovery apparatus, and more particularly to a winch type oil extraction apparatus and a method of manufacturing the same. Background technique
  • the beam pumping unit is commonly used in mechanical oil recovery.
  • the beam pumping unit is the bottom power equipment of the downhole pumping pump. It is commonly known as the steaming machine. It transmits the reciprocating motion of the pumping point of the pumping unit through the sucker rod.
  • Downhole plunger pump when pumping oil, the transmission of the motor through the gearbox and crank linkage structure becomes the up and down movement of the hammer.
  • the hammer passes the plunger and the sucker rod to drive the plunger of the underground deep well pump to move up and down, thus continuously Drain the oil or oily liquid from the well out of the wellbore.
  • This type of oil recovery of the beam pumping unit is suitable for oil wells with large oil production.
  • the beam pumping unit can quickly and uninterruptedly extract oil or oily liquid from the oil well, but for low oil production. Oil wells, due to insufficient oil supply in the formation, the oil level recovery of the oil wells is slow.
  • the dry pumping phenomenon often occurs, which causes the loss of electric energy and also causes wear and tear on the equipment. If you want to wait for the liquid level to recover after pumping, you must rely on manual control of the pumping unit to start and shut down, and the time to manually control the pumping unit to start and shut down is not easy to master. Manually controlling the pumping unit to start and shut down is not easy to cause the card.
  • the pumping unit is generally set in the field, it requires all-weather work, and manual control increases the operating cost, which brings inconvenience to the production.
  • the beam pumping unit has a complicated structure, high cost, large floor space, and cannot be used in some places where the available space is small.
  • the object of the present invention is to overcome the problems existing in the prior art described above, and to provide a winch type pulling and oil recovery system, which adopts a control device and a downhole detecting device to intelligently control the working and stopping of the oil production system, thereby ensuring each time.
  • the oil consumption of the oil avoids the phenomenon of dry pumping, improves the efficiency of oil recovery, reduces the energy consumption and reduces the wear of the equipment.
  • the intelligent winch type oil extraction system has a simple structure and a small footprint.
  • Another object of the present invention is to provide a method for manufacturing a wicking rope suitable for use in a hoisting and pulling oil recovery system for manufacturing a oil-impregnated oil wicking rope, thereby preventing the ordinary steel wire rope from being pulled during the pulling process.
  • the underground crude oil is carried to the working face of the well to avoid environmental pollution and waste of crude oil.
  • an intelligent winch type oil extraction system of the present invention comprises: a drive assembly having a reel and a drive device for driving the reel to rotate; a frame mounted on the ground and having a pulley mounted thereon
  • the oil recovery device is located in the column of the underground oil well; the oil suction rope is wound on the reel at one end, and the oil recovery device is connected to the pulley at the other end; and the control device is used to drive the revolving of the reel by controlling the rotation of the driving device, thereby
  • the oil recovery device is driven by the oil sling to perform the repeated lifting and oil recovery operation, wherein the oil recovery device is provided with a downhole liquid column height detector for controlling the control device when detecting that the liquid collected underground reaches the set liquid column height
  • the oil recovery device performs the lifting and oil recovery operation.
  • the height of the downhole liquid column refers to the height of the liquid column in the oil well string
  • the downhole liquid column height detector detects when the liquid collected in the underground reaches the set liquid column height by wired or wireless transmission.
  • the liquid column height signal is transmitted to the control device, so that the control device drives the driving device to drive the reel when receiving the expected liquid column height signal, and then the reel is driven by the reel to drive the oil recovery device into the oil column.
  • a liquid with a predetermined column height is pulled out of the well.
  • the oil recovery device is further provided with an expandable pump for pulling up the liquid in the oil well tubular string
  • the pumping device is provided with one or more hard polymer material cylinders whose diameter is smaller than the inner diameter of the oil well tubular string,
  • the upstream speed of the oil recovery device is 0.2m/ s to 1.2m/ s , it is compressed under the upward pulling force and the liquid gravity in the oil well string, and the diameter expansion of the rubber cylinder is equal to the inner diameter of the oil well tubular string.
  • the oil well pipe string is connected by a plurality of oil pipes, and the connection gap between the oil pipes is small enough for the polymer material rubber cylinder to smoothly slide in the oil pipe to avoid damage caused by excessive gap.
  • the downhole liquid column height detector is connected to the other end of the oil sucking rope, and includes: a pressure transmitter for detecting the pressure corresponding to the liquid height collected by the well, having a pressure measuring hole, and the pressure transmitter is disposed by a pressure transmitter housing and a space formed by a sealing steel body connected to the pressure transmitter housing; the sealing steel body is provided with a pressure transmitting hole connecting the external liquid and the pressure measuring hole, so as to be in the oil well tubular column The pressure corresponding to the liquid level is transmitted to the pressure transmitter.
  • the sealed steel body has an electrically conductive contact member in contact with an outer oil well tubular string; the pressure transmitter is electrically connected to the metal core of the oil sucking rope on the one hand, and the pressure transmitter on the other hand
  • the outer casing is electrically connected to transmit the detected signal of the downhole liquid column to the control device through the oil drawstring and the oil well string.
  • the conductive contact member includes a plurality of pairs of steel balls disposed in the sealed steel body, each pair of the plurality of pairs of steel balls is placed in a radial direction, and the two steel balls are connected by a spring such that the two steel balls are radially outward under the action of the spring Prominent so that the steel ball contacts the inner wall of the oil well string.
  • the wicking rope has two communication cables, and the pressure transmitters are electrically connected to the two communication cables respectively, so that the signals of the detected downhole liquid column are transmitted to the communication cable through the hoisting rope.
  • the pressure transmitter has a wireless transmitting unit that transmits the detected signal of the downhole liquid column to the control device via the wireless transmitting unit.
  • the oil well pipe string is formed by connecting a plurality of oil pipes through the coupling, and a nylon ring or a steel ring or a protrusion on the inner wall of the coupling is arranged between the adjacent oil pipes to reduce the connection gap between the adjacent oil pipes.
  • the inner diameter of the nylon or the inner diameter of the steel ring is consistent with the inner diameter of the tubing.
  • a depth speed detecting device is further mounted on the pulley, and an encoder is further mounted on the driving device.
  • a method for manufacturing a wicking rope of a hoisting and pulling oil recovery system of the present invention comprises: using a tanning device to form a plurality of steel strands into a sealing steel cord;
  • An outer protective seal layer is applied to the outer surface of the screen to enclose the screen and the sealing steel cord therein.
  • the tantalum sealing steel rope is manufactured as follows:
  • the sealing steel cord is subjected to a stress relief treatment to remove the internal machining stress of the sealing steel cord.
  • junction point is heated while the junction point is being filled, so that the infused filler is in a state of being viscous, so as to fill the internal gap space of the steel strand.
  • the woven wire mesh is manufactured as follows:
  • the wire strand and the wire strand of the wire mesh are respectively made of a plurality of steel wires, and are filled at a joint point of the wire twisting, so that the filled filler fills the gap space inside the wire.
  • coating the outer protective seal layer comprises the following steps:
  • the above method further comprises: sequentially processing the steel cord coated with the outer protective sealing layer as follows:
  • the column height of the collected crude oil is detected by the downhole liquid column height detector, and the column height is reached.
  • the control device controls the driving device to lift the crude oil in the oil column, and the pumping column height can be set at will, and the intelligent control can be realized, thereby improving the oil recovery efficiency, reducing the useless work, and saving electricity;
  • the crude oil output can be accurately calculated to achieve standard measurement; and the real-time measurement of the liquid level can be achieved by the change of the pressure detected by the downhole liquid column height detector;
  • the pressure transmitter and the control device pass the metal core of the oil sling and the oil well pipe string, or the communication cable is set in the oil sling rope, or the signal is transmitted through the wireless transmitting unit, and the pressure transmitter
  • the connection with the oil well string is realized by the steel ball, and the structural design is simple and reliable;
  • the load is small, the small power motor can be configured to save energy
  • the minimum gap connection between the oil well string can reduce the damage of the rubber tube of the oil recovery device, which not only can extend the life of the rubber cylinder, but also help to improve the oil recovery efficiency and reduce the bottom form of the wear inner layer;
  • the oil recovery reel is wrapped around the oil suction rope as the power device for oil recovery.
  • the structure design is simpler, the floor space is small, and the cost is low.
  • the rubber cylinder When the rubber cylinder is up, it seals and slides on the inner wall of the oil well string, the leakage is small, the pump efficiency is high, and a lot of useless work is reduced. The efficiency of convulsions has increased significantly.
  • FIG. 1 is a schematic view showing the overall structure of an intelligent winch type pulling and oil recovery system of the present invention
  • FIG. 2 is a side elevational view of the drive assembly of the intelligent winch type oil extraction system of the present invention
  • Figure 3 is a front elevational view of the cord winding device of the intelligent winch type oil extraction system of the present invention
  • Figure 3a is a side view of the cording device
  • Figure 3b is a top plan view of the rope arranging device
  • Figure 3c is a schematic view of the working principle of the rope arranging device
  • FIG. 4 is a schematic structural view of a first embodiment of a downhole liquid column height detector of the intelligent winch type oil extraction system of the present invention
  • FIG. 4a is a schematic structural view of a second embodiment of a downhole liquid column height detector of the intelligent winch type oil extraction system of the present invention.
  • 4b is a schematic structural view of a third embodiment of a downhole liquid column height detector of the intelligent winch type oil extraction system of the present invention.
  • Figure 5 is a schematic structural view of the pump of the intelligent winch type oil extraction system of the present invention.
  • FIG. 6 is a schematic structural view of the first embodiment of the oil well pipe connection of the intelligent winch type oil extraction system of the present invention
  • FIG. 6a is a schematic structural view of the second embodiment of the oil well pipe connection of the intelligent winch type oil extraction system of the present invention
  • 6b is a schematic structural view showing a third embodiment of the oil well pipe connection of the intelligent winch type oil extraction system of the present invention
  • FIG. 7 is a control principle diagram of the control device of the present invention
  • FIGS. 8 and 8a are flow charts showing the production process of the sealed steel cord in the method for manufacturing the flexible oil wicking rope of the present invention
  • Figure 9 is a process flow diagram of a woven wire mesh for sealing steel wire
  • 10a, 10b are process flow diagrams for applying an outer protective seal layer to the outer surface of the screened sealing steel wire produced in Fig. 9;
  • Figure 11 is a process flow diagram of calendering and sizing treatment of the oil wicking rope obtained by the above process
  • Figures 12, 12a are schematic cross-sectional views of a wicking rope made using the method of the present invention.
  • 60-fishing head 61-connecting sleeve; 61a-seal ring; 62-pressure transmitter; 62a-pressure tapping hole; 62b-pressure transmitter housing; 62c-insulating sleeve; 62d-wireless transmitting unit; Steel body; 63a-pressure transmission hole; 63b-steel ball; 63c-spring; 64- quick joint; 64a-cylindrical structure; 64b-round hole; 64c- strip hole;
  • 70 center tube; 71-upper joint; 71a-round head; 71b-cylindrical top; 71c-cylindrical bottom; 71d-oil inlet; 72-lower joint; 72a-round head; 72b- Cylindrical top; 72c-cylindrical bottom; 72d-oil inlet; 73-Versail; 74a-back cap; 74b-pressure cap; 75-feed block; 75a-feed hole; 76a, 76b-hard Plastic polymer material cartridge; 77- connection block;
  • 81- outer protective sealing layer 82-wire mesh, 83, 83a-sealing steel rope; 84-steel wire strand; 84a-junction intersection; 85-communication cable strand; 86-filler; 87-steel wire; 23, 23a- Pumping rope; 89-communication wire; 811-player; 812-communication wire; 813- tanning machine; 814-filler; 815-temperature control die; 815a-heating body; 815b-filling hole ; 816-stress reducer; 817- tractor; 819-winding machine;
  • 821-winding machine 822-woven machine; 823-controllable heating box; 824-roller type tighter; 825-tractor; 826-seal steel wire with screen; 827-winding machine;
  • 831-winding machine 832-extruder; 833-cold water tank; 834-tractor; 835-steel rope coated with outer sealing layer; 836- wire take-up machine; 837-vulcanized line;
  • the intelligent winch type oil extraction system of the present invention includes: a drive assembly 1 disposed on the ground base 10 and having a winding structure. a reel 11 of the wicking rope 23 and a motor 12 for driving the reel 11; a frame 2 mounted on the ground, on which a pulley 21 is mounted; an oil recovery device 4 disposed in the downhole oil column 5; 23, one end is wound on the reel 11, and the other end is connected to the oil recovery device 4 around the pulley 21 on the frame 2.
  • the control device 9 is used to control the rotation of the motor 12 to drive the reel 11 to rotate, thereby passing the oil sling 23 drives the oil recovery device 4 to perform the lifting and oil recovery operation.
  • the oil production device 4 is provided with a downhole liquid column height detector 6 for causing the control device 9 to control the oil recovery device 4 to perform a pulling operation when detecting that the liquid collected underground reaches the set liquid column height. .
  • the downhole liquid column height detector 6 transmits the detected liquid column height signal to the control device by wired or wireless transmission when detecting that the liquid collected underground reaches the set liquid column height, so that the control device 9 is
  • the control motor 12 drives the reel 11 to rotate, and the reel 11 is driven by the reel 11 to drive the oil recovery device 4 to pull the oil or oily liquid of the expected column height in the oil well string 5 to the outside of the well.
  • the oil recovery device 4 is further provided with a pumping 7 for pulling oil or oily liquid in the oil well string 5 (as shown in Fig. 5), and the pumping unit 7 is provided with one or more hard high diameters smaller than the inner diameter of the oil well tubular string.
  • the molecular material rubber cylinders 76a, 76b and the hard polymer material rubber cylinders 76a, 76b are in the upward pulling force and the oil or oily liquid in the oil well string 5 when the oil production device 4 has an upward velocity of 0.2 m/s to 1.2 m/s. Compressed under the force of gravity to make the diameter equal to the inner diameter of the oil column.
  • the oil well string 5 is directly connected to the tree 42 on the ground, and the tree 42 is connected to the oil inlet line 43 through a single flow valve 42a.
  • a blowout prevention box 41 is arranged above the tree 42 to prevent oil pumping.
  • the oil wicking rope 23 passes through the blowout prevention box 41 in sequence, and the oil tree 42 is connected with the oil recovery device in the oil well pipe string 5, and the oil sling rope
  • the oil recovery device 4 is driven up in the oil well string 5
  • the petroleum or oily liquid in the oil well string 5 is lifted upward, and the petroleum or oily liquid rises from the oil well string 5 to the tree 42 and then from the tree 42.
  • the reel 11 is mounted on the base 10 through the reel shaft 11a, and the reel 11 can be relatively aligned with the reel shaft 11a as shown in the side view of the drive assembly of the intelligent winch type oil extraction system of the present invention.
  • the base 10 rotates, and one side of the spool shaft 11a is mounted with a driven wheel 110.
  • the output shaft of the motor 12 is mounted with a driving wheel 120.
  • the driving wheel 120 and the driven wheel 110 are connected by a chain belt 13.
  • the motor output shaft drives the driving wheel 120 to rotate, and the driving wheel 12 drives the driven wheel 110 to rotate through the chain belt 13.
  • the driven wheel 110 is coaxial with the reel 11, the driven wheel 110 rotates to drive the winding coaxial 11a.
  • the drum 11 is rotated, the reel 11 is rotated, and the reel 11 is wound around the oil slinger 23, so that the slinger 23 drives the oil recovery device 4 to perform the oil recovery operation.
  • the drive assembly 1 of the present invention also has a rope arranging device 3 which is disposed between the spool 11 and the pulley 21.
  • the rope arranging device 3 has vertical brackets 30 mounted on the base 10 at the front and rear sides. The lower ends of the two vertical brackets 30 are connected by a horizontal bracket 30a, and the upper ends are connected by a horizontal rail 30b.
  • the guide rail 30b is formed by two channels of steel placed opposite each other, and the two channels of steel are separated by a certain distance, as shown in FIG. As shown in Fig.
  • the left end of the horizontal bracket 30a is mounted with a transmission large sprocket 35 which is mounted on the horizontal bracket 30a via a transmission shaft 35a, and the drive shaft 35a is mounted on the outer side of the transmission large sprocket 35.
  • the transmission small sprocket 35b, the upper end of the vertical bracket 30 is disposed below the horizontal rail 30b, and the sprocket sprocket 36 is mounted on the vertical bracket 30 via the drive shaft 36a, the sprocket 36 and the transmission
  • a tension pulley 37 is further disposed between the small sprocket wheels 35b, and the rope sprocket 36, the tension pulley 37, the transmission large sprocket 35, and the transmission small sprocket 35b are all located outside the left vertical bracket 30, and are arranged at the same time.
  • the rope sprocket 36, the tensioning pulley 37, and the transmission small sprocket 35b are located in the same plane, and the rope sprocket 36 and the transmission small sprocket 35b are connected by the transmission chain 15, and the tensioning wheel 37 is tensioned on the transmission chain 15.
  • the roll coaxial 11a is also provided with a reel sprocket 111 on the outer side of the driven wheel 110, as shown in FIG. 2, and the reel sprocket 111 and the transmission large sprocket 35 are in the same plane, the reel sprocket 111 and the transmission The large sprocket wheels 35 are connected by a transition chain 14 (as shown in Figure 1).
  • the motor 12 rotates to rotate the spool shaft 11a
  • the spool 11 mounted on the spool shaft 11a rotates to drive the oil sucking rope 23 to pull up the oil recovery device 4, and is mounted on the coil coaxial 11a.
  • the upper reel sprocket 111 also rotates, and the reel sprocket 111 drives the transmission large sprocket 35 to rotate through the transition chain 14. Since the transmission small sprocket 35b is coaxial with the transmission large sprocket 35, the transmission large sprocket 35 also rotates.
  • the transmission small sprocket 35b is rotated, and the transmission small sprocket 35b drives the rope sprocket 36 to rotate through the transmission chain 15, so that the rotation of the reel to the rope arranging device 3 is realized.
  • the rope sprocket 36 is mounted on the vertical bracket 30 via the drive shaft 36a, and the driving bevel gear 38a is mounted on the inner side of the vertical bracket 30 on the drive shaft 36a; the bottom of the horizontal rail 30b is left and right.
  • Two ears are respectively protruded downward on both sides, and sprocket shafts 39a, 39b are respectively mounted on the two ears, and the two sprocket shafts 39a, 39b are just equal to the drive shaft 36a, and two ends of the two sprocket shafts 39a, 39b are respectively mounted
  • a pair of sprockets 39 on the left sprocket shaft 39a are respectively fixed to the sprocket shaft 39a by bolts, so that the pair of sprockets 39 simultaneously rotate with the sprocket shaft 39a relative to the lugs;
  • a pair of sprockets 39' on the side sprocket shaft 39b are respectively mounted on the sprocket shaft 39b by bearings, and the right sprocket shaft 39b is fixed on the right side lugs, so that the pair of sprockets 39' are respectively opposite to the right sprocket shaft 39b turns.
  • the right pair of sprocket wheels 39 and the left pair of sprocket wheels 39' are respectively connected by two rows of chain chains 31 (only one of the row of rope chains 31 is shown in Fig. 3a).
  • a driven bevel gear 38b is mounted between the pair of sprockets 39 on the left sprocket shaft 39a, and the driven bevel gear 38b just engages with the driving bevel gear 38a.
  • the horizontal rail 30b is further provided with a sliding trolley including two sliding plates 32 on the front and rear sides of the horizontal rail 30b.
  • the two sliding plates 32 are connected to each other at the top of the horizontal rail 30b by bolts, so that the two sliding plates 32 are spanned.
  • On the horizontal rail 30b two rows of the chain 31 are respectively located inside the two slide plates 32.
  • the two slide plates 32 respectively extend from the top of the horizontal rail 30b to the lower row of the rope chain, and the two slide plates 32 are respectively provided with positioning grooves 32a.
  • the positioning groove 32a extends from the lower row of the rope chain to the upper row of the rope chain, and the slider chain 31 is fixed with the slider 31a, and the slider 31a protrudes outward through the positioning groove 32a of the slider 32, thereby
  • the slide plate 32 is coupled to the rope chain 31.
  • a plate 32b is protruded downward from the top, and the support plate 32b is located between the two grooved steels forming the horizontal guide rail 30b.
  • a row of rollers is arranged at the front and rear ends of the support plate 32b.
  • each row comprises three rollers, each roller is fixedly connected to the support plate 32b through a pin shaft, so that the two rows of rollers are located in the two channel steels respectively, in order to clear the display plate 32b and the roller in FIG. 3b
  • the connection eliminates the portion of the skateboard 32 and its top.
  • the height of one roller in the middle of each row of rollers is higher than that of the other two rollers (as shown in Fig. 3a), so that the middle roller is pressed against the top plate of the channel steel, and the other two rollers are pressed against the bottom plate of the channel steel, as shown in Fig. 3.
  • the structure of the horizontal guide rail 30b is omitted in Fig. 3 to omit the structure of the roller 33 and the support plate 32b.
  • the tops of the two slide plates 32 are also juxtaposed with two rows of rope vertical rollers 34.
  • the two rows of rope vertical rollers 34 have a certain gap therebetween, and the oil sucking ropes 23 pass between the two rows of rope vertical rollers 34.
  • a plurality of plates extend from the tops of the two rows of vertical rollers 34, and the limit plates 34a are mounted on the support plates through the pins to ensure that the oil drawstrings 23 are always located between the two rows of vertical rollers 34.
  • the distance between the left and right sprocket wheels 39, 39' should be equal to the length of the reel 11 to ensure that the sliding carriage moves from left to right once and the wicking rope 23 is evenly wound around the reel 11.
  • the wicking rope 23 also moves from right to left along with the sliding carriage, so that the wicking rope 23 is gradually entangled from the right to the left on the reel 11; when the sliding trolley moves to the leftmost end of the lanyard chain 31, this When the wicking rope 23 is also wound around the leftmost end of the reel 11, the winding of the layer on the reel 11 is completed, as shown in Fig. 3a, since the slinging chain 31 will continue to circulate at this time, at this time, The slider 31a on the rope chain 31 moves from the lower row of the chain to the upper row of chains, and the slider 32 cannot move up and down, so that the slider 31a can only move from the bottom to the top of the positioning groove 32a at the positioning groove 32a.
  • the slider 31a will As the movement of the rope chain 31 moves with the entire sliding carriage from left to right on the horizontal rail 30b, the oil wicking rope 23 sandwiched between the two rows of rope vertical rollers 34 also moves from left to right along with the sliding carriage. Thus, the wicking rope 23 is gradually wound from the left to the right on the reel 11, and the winding of the second layer is performed, and the operation is continued until the motor 11 stops operating, and the reel 11 stops rotating.
  • the oil recovery device 4 of the intelligent winch type oil extraction system of the present invention as shown in Fig. 1 includes a downhole liquid column height detector 6, a pump 7 and a weighting rod 8 which are connected in order from the top to the bottom.
  • the structure of the downhole liquid column height detector of the present invention will be described in detail below with reference to Figs. 4, 4a, 4b.
  • the downhole liquid column height detector 6 of the present invention comprises a fishing head 60, a connecting sleeve 61, a pressure transmitter housing 62b and a sealing steel body 63 which are arranged from top to bottom and sequentially threaded, and the fishing head 60.
  • the connecting sleeve 61 and the pressure transmitter housing 62b each have an inner cavity, and a pressure transmitter 62 is disposed in the inner cavity of the pressure transmitter housing 62b, and the oil sucking rope 23 is wrapped with an insulating layer, and the oil sucking rope 23 is sequentially
  • the inner cavity of the fishing head 60 and the connecting sleeve 61 is connected to the pressure transmitter housing 62b in the inner cavity of the pressure transmitter housing 62b, and the pressure transmitter 62 is electrically connected to the metal core of the oil wicking line 23.
  • the pressure transmitter housing 62b and the sealing steel body 63, and the electrically conductive contact members on the sealing steel body 63 are electrically connected to the oil pipe 5.
  • the top of the inner cavity of the connecting sleeve 61 is provided with a sealing ring 61a, and the sealing ring 61a is set on the oil sucking rope 23, when will be connected
  • the sealing ring 61a is expanded, so that the sealing ring 61a is tightly coupled with the oil sucking rope 23 and the connecting sleeve 61, the oil pipe 5
  • the oil or oily liquid inside does not enter the inner cavity of the connecting sleeve 61 by the gap between the fishing head 60 and the wicking rope.
  • the upper end of the inner cavity of the pressure transmitter housing 62b is provided with an insulating sleeve 62c, and the end of the oil sucking rope 23 passes through the insulating sleeve 62c and is connected with the rope head pressing rope 23a to lock the end of the oil sucking rope 23 In the insulating sleeve 62c, when the oil wicking rope 23 ascends, its end does not come out of the insulating sleeve 62c, thereby achieving the connection of the oil wicking rope 23 to the pressure transmitter housing 62b.
  • the sealing steel body 63 is sealed at the bottom of the pressure transmitter housing 62b, and the pressure transmitter 62 is sealed in the inner cavity of the pressure transmitter housing 62b.
  • the pressure transmitter 62 is provided with a pressure measuring hole 62a at the bottom of the pressure transmitter 62.
  • the body 63 is provided with a pressure transmitting hole 63a for connecting the oil or oily liquid in the oil well string 5 and the pressure measuring hole 62a, so that the pressure of the liquid in the oil well string 5 is transmitted to the pressure transmitter 62 through the pressure transmitting hole 63a.
  • a hole 62a a seal ring is disposed between the bottom of the pressure transmitter 62 and the inner wall of the pressure transmitter housing 62b, so that the liquid in the oil well string 5 is transmitted from the pressure transmitting hole 63a to the pressure transmitter 62.
  • liquid does not enter the interior of pressure transmitter housing 62b.
  • the sealing steel body 63 is further provided with a conductive contact member, comprising a plurality of pairs of steel balls 63b, each pair of the plurality of pairs of steel balls are arranged in a radial direction, and the two steel balls are connected by a spring 63c, and the two steel balls are at the spring 63c Under the action, it protrudes radially outward, so that the steel ball contacts the inner wall of the oil well string 5.
  • the pressure transmitter 62 is also electrically connected to the pressure transmitter housing 62b. Since the pressure transmitter housing 62b is screwed to the sealing steel body 63, the sealing steel body 63 is in contact with the oil well string 5 through the steel ball 63b, so the pressure is changed.
  • the liquid pressure signal corresponding to the height of the downhole liquid column measured by the feeder 62 can be transmitted to the ground control device 9 through the oil sucking rope 23 and the oil well string 5, respectively, when the control device 9 receives the pressure corresponding to the expected liquid column height.
  • the motor 12 is controlled to operate, thereby driving the reel 11 to perform the action of winding the oil slinger 23, so that the wicking rope 23 pulls up the oil recovery device to perform the oil recovery operation.
  • a plurality of sets of conductive contact members may be disposed on the sealing steel body 63.
  • the conductive contact members in FIG. 4 are two groups arranged one above the other to ensure that the downhole liquid column height detector 6 is in the process of ascending with the oil sucking rope 23.
  • the steel ball is always in contact with the inner wall of the oil well string 5 in the conductive contact member, thereby ensuring that the pressure signal of the downhole liquid can be smoothly transmitted to the ground.
  • FIG. 4a is a schematic illustration of a second configuration of the downhole liquid column height detector 6 of the present invention.
  • the oil wicking rope 23 of the present invention is wrapped with an insulating layer, and has two communication cables 23b inside.
  • the oil wicking rope 23 is electrically connected to the pressure transmitter 62 through two communication cables 23b, so as to be
  • the pressure signal corresponding to the height of the downhole liquid column measured by the pressure transmitter 62 is transmitted to the control device 9 on the ground.
  • the control device 9 receives the pressure signal corresponding to the expected liquid column height, the motor is controlled to operate, thereby driving the reel 11
  • the action of winding the oil wicking line 23 is performed so that the oil slinger 23 pulls up the oil recovery device to perform oil recovery work.
  • the other structure of the downhole liquid column height detector 6 is the same as that of the first structure and will not be repeated here.
  • FIG. 4b is a schematic illustration of a third configuration of the downhole liquid column height detector 6 of the present invention.
  • a pressure transmitter 62 is disposed in the inner cavity of the pressure transmitter housing 62b of the present invention.
  • the pressure transmitter 62 has a wireless transmitting unit 62d, and the oil sucking rope 23 is wrapped with an insulating layer and a pumping rope. 23 is in turn connected through the inner portion of the fishing head 60 and the connecting sleeve 61 and the top of the pressure transmitter housing 62b to the pressure transmitter 62.
  • the pressure signal corresponding to the height of the downhole liquid column measured by the pressure transmitter 62 is transmitted to the ground control device 9 through the wireless transmitting unit 62d, and controls the motor to work when the control device 9 receives the pressure signal corresponding to the expected liquid column height, thereby The reel 11 is driven to wind the oil slinger 23, so that the oil slinger 23 pulls up the oil recovery device to perform the oil recovery operation.
  • the other structure of the downhole liquid column height detector 6 is the same as that of the first structure and will not be repeated here.
  • the bottom of the sealing steel body 63 shown in Figures 4, 4a, 4b is provided with a quick joint 64 having a cylindrical structure 64a, and the side wall of the cylindrical structure 64a is provided with a circular hole 64b, the circular hole 64b A strip hole 64c is formed in the bottom.
  • 5 is a schematic structural view of the pump 7 of the present invention.
  • the pump 7 includes a center tube 70.
  • the upper end of the center tube 60 is screwed with an upper joint 71, and the lower end is screwed with a lower joint 72.
  • the upper joint 71 has The cylindrical bottom portion 71c and the cylindrical top portion 71b have the same diameter as the strip-shaped hole 64c, and the upper end of the cylindrical top portion 71b is provided with a circular projection 71a having a diameter of a projection hole 71b and a circular hole 64b.
  • the same diameter, the circular projection 71a is fastened In the circular hole 64b of the speed joint 64, the cylindrical top portion 71b is snapped into the strip hole 64c, thereby quickly connecting the upper joint 71 and the sealing steel body 64, so as to realize the connection of the pump 7 to the downhole liquid column height detector 6. .
  • the bottom end of the cylindrical bottom portion 71c of the upper joint 71 is screwed onto the center tube 70, and the upper end circumferential wall of the cylindrical bottom portion 71c of the upper joint 71 is provided with a plurality of liquid inlet holes 71d, and the external liquid can be filled by the liquid inlet hole 71d enters the cylindrical bottom 71c.
  • the lower joint 72 has the same structure as the upper joint 71, the lower joint 72 is inverted, and the bottom end of the cylindrical bottom portion 72c is screwed to the bottom of the center tube 70; the lower joint 72 is used to realize the rapid movement of the drawer 7 and the weighting rod 8. connection.
  • a Versaille 73 is placed on the top of the center tube 70, and the Victoria 73 seals the top end of the center tube 70.
  • the bottom of the center tube 70 at the bottom of the upper joint 71 is threaded with a back cap 74a, the back cap 74a is tight against the bottom of the upper joint 71, and the back cap 74a is tight against the upper joint.
  • the bottom of the center tube 70 is mounted on the top of the lower joint 72 by a pressure cap 74b, and the pressure cap 74b is tightly pressed against the cylindrical bottom portion 72c of the lower joint 71 to prevent the pumping of the pumping rope
  • the threaded connection between the upper joint 71 and the lower joint 72 and the center tube 70 is released.
  • the central pipe 70 is disposed under the back cap 74a with an indentation block 75.
  • the inner wall of the advancing block 75 has a certain gap between the inner wall of the central pipe 70, and the advancing block 75 is extended by the outer wall of the advancing block 75.
  • the pressure hole 75a of the inner wall of the pressure block 75; the central tube 70 is provided with two hard polymer material cartridges 76a, 76b between the pressure piece 75 and the pressure cap 74b, and the center tube 70 is located at two hard heights.
  • a connecting block 77 is also disposed between the molecular material cartridges 76a and 76b.
  • the two rigid polymer material cartridges 76a and 76b and the inner wall of the connecting block 77 also have a certain gap between the inner wall of the central tube 70 and the outer wall of the central tube 70.
  • the gap between the inner wall of the inlet block 75 and the outer wall of the center tube 70 can be entered by the pressure inlet hole 75a of the pressure injecting block 75, thereby entering the inner walls of the two rigid polymer material cartridges 76a, 76b and the connecting block 77.
  • the upward speed of the pump is preferably 0.6 m/s or more.
  • the liquid in the oil well string 5 enters the center tube 70 from the liquid inlet hole 72d of the lower joint 72, and moves upward in the center tube 70 with the descending liquid of the pumping unit.
  • the Versail ball 73 enclosed at the top end of the center tube 70 floats away from the top end of the center tube 70 by the liquid upward, so that the top of the center tube 70 is opened, and the liquid flows out from the top of the center tube through the oil inlet hole 71d of the upper joint 71.
  • the liquid does not enter the gap between the inner walls of the two rigid polymer material cartridges 76a, 76b and the connecting block 77 and the outer wall of the central tube 70 from the pressure inlet hole 75a, and the two hard polymer material cartridges 76a 76b generates pressure, so the two rigid polymer material cartridges 76a, 76b do not expand, so that the hard polymer material rubber cylinder and the inner wall of the oil well tubular string 5 are separated by a certain distance, and the pumping is unobstructed.
  • the oil well string 5 of the present invention is a fuel pipe that eliminates the connection gap.
  • the oil well string 5 is connected by a plurality of fuel pipes through a coupling 51.
  • a nylon ring 53 is placed between the adjacent oil pipes 5a, 5b, and the inner diameter of the nylon ring 53 and the adjacent two oil pipes 5a, 5b
  • the inner diameter of the nylon ring 53 is larger than the outer diameter of the adjacent two oil pipes 5a, 5b, and the coupling 51 is screwed on the adjacent end portions of the two oil pipes 5a, 5b, thereby tightening the two oil pipes 5a, 5b. Tightly joined together to reduce the joint gap between adjacent oil pipes 5a, 5b.
  • the inner diameter of the steel ring 53' is the same as the inner diameter of the adjacent two oil pipes 5a, 5b, and the outer diameter of the steel ring 53' is smaller than the phase.
  • the coupling 51 Adjacent to the outer diameters of the two oil pipes 5a, 5b, the coupling 51 is screwed on the adjacent end portions of the two oil pipes 5a, 5b, so that the two oil pipes 5a, 5b are tightly connected together to reduce the adjacent two A connection gap between the oil pipes 5a, 5b.
  • a ring protrusion 52 on the inner wall of the coupling 51.
  • the shape of the upper and lower end faces of the protrusion 52 matches the shapes of the adjacent end portions of the two oil pipes 5a, 5b, and the coupling is matched.
  • the projection 52 is just caught between the adjacent end portions of the two oil pipes 5a, 5b, thereby tightening the two oil pipes 5a, 5b. Connected together to reduce the joint gap between adjacent oil pipes 5a, 5b.
  • the intelligent winch type oil extraction system of the present invention is further provided with a depth speed detecting device 21a on the pulley 21.
  • the depth speed detecting device 21a is connected to the control device 9 for detecting that the pulley 21 is rotated. The number of turns is calculated to calculate the depth of the down line or the upward direction of the wicking line 23, and the signal is transmitted to the control device 9.
  • the motor 12 is further provided with an encoder 12a, as shown in Fig. 1, for calculating the rotational speed of the motor 12 to calculate the depth of the hoisting rope 23 up or down.
  • the base 10 of the ground is further provided with a brake device including a hydraulic thruster 18 connected to the control device 9, a brake 18a connected to the output shaft of the hydraulic thruster 18, and a brake 18a.
  • a brake device including a hydraulic thruster 18 connected to the control device 9, a brake 18a connected to the output shaft of the hydraulic thruster 18, and a brake 18a.
  • a counterweight 18b and a brake band 18c that is in contact with the driven wheel 110.
  • FIG. 7 shows the principle of the control device 9 of the present invention.
  • the control device is composed of a programmable virtual controller or a microprocessor, and receives a downhole pressure detection signal sent by the downhole liquid column height detector to convert the downhole pressure value into a liquid column.
  • the height value and when the liquid column height value is greater than or equal to the preset expected liquid column height value, the geared motor is rotated by the soft starter to drive the reel to rotate, so that the wicking rope wound on the reel moves upward.
  • a crude oil or oily liquid that is expected to be at the height of the liquid column.
  • the programmable controller controls the position of the oil recovery device 4 by receiving the depth and up and down speed signals from the oil recovery device 4 of the depth velocity detector.
  • the depth detector can be installed on the side of the large pulley of the derrick, and the depth and speed of the downcomer connected to the oil recovery device 4 are calculated by counting the number of turns of the large pulley.
  • the programmable controller is connected to a control button for inputting a control signal, and is also connected to a liquid crystal display for displaying liquid column height information, depth/speed information.
  • the programmable controller is further connected with an encoder for providing the speed of the geared motor, thereby calculating the rotation of the drum, and determining the number of turns of the normal rotation of the pulley by using the rotation of the drum, thereby detecting a fault such as slipping of the pulley, and In the event of a fault on the pulley, a shutdown is performed.
  • the programmable controller also connects a brake for braking and a current transformer for detecting the running current of the geared motor, and performs a shutdown operation when detecting that the geared motor is overcurrent or overloaded.
  • the programmable controller is also connected to a remote mobile communication unit for communication with the maintenance/management center. It can notify the operation information such as oil production and fault information such as excessive current or overload of the geared motor and slipping of the pulley. Maintenance / Management Center.
  • the hydraulic thruster 18 is loaded, causing the brake 18a to drive the brake band 18c away from the driven wheel 110, the motor
  • the pressure transmitter 62 transmits the detected change of the downhole pressure to the control device 9, and the control device 9 determines that the pump 7 has reached the liquid level, which is the liquid level depth, thus Real-time detection of the liquid level is possible.
  • the pump 7 continues downward, when the depth speed detecting means 21a on the pulley 21 detects that the pump 7 has not yet reached the set pumping
  • the control device 9 controls the motor 12 to rotate in the reverse direction, and drives the drum 11 to rotate in the opposite direction to wind the oil drawstring.
  • the wicking rope 23 is stopped to turn to the upper pumping; and when the depth speed detecting device 21a on the pulley 21 detects that the pumping 7 is descending to the set suction depth, the pressure transmitter 62 detects the pumping 7
  • the control device 9 controls the motor 12 to stop rotating, and the hydraulic thrust device 18 is unloaded, so that the brake 18a drives the brake band 18c and the driven wheel 110 under the action of the weight 18b.
  • the suction height is controlled, and the control device 9 controls the hydraulic thruster 18 to be loaded, so that the brake 18a drives the brake belt 18c to disengage from the driven wheel 110, and the motor 12 starts to rotate in the reverse direction, and the reel 11 is also rotated in the opposite direction to perform the winding.
  • the liquid column of the pump 7 or more is lifted by the hard polymer material cartridges 76a, 76b until the oil recovery device 4 reaches the top of the oil well string 5.
  • the liquid column of 7 or more is pumped into the tree 42 so that a pumping operation is completed.
  • the depth speed detecting means 21a on the pulley 21 detects that the upward depth of the sucking rope 23 has reached the insurance value, the depth speed detecting means 21a transmits a signal to the control means 9, and the control means 9 controls the motor 12 to rotate again, the reel 11 Further, the operation of discharging the oil wicking rope 23 is performed, and the oil slinging rope 23 is further descended by the weighting rod 8 and the motor 12, and the oil recovery device 4 descends in the oil well tubular string 5 to perform the next oil pumping operation.
  • the total output of crude oil can be measured to achieve the standard of crude oil production.
  • S suction wick 23 of the present invention is not contaminated with oil as a flexible cable, since the wire ropes having oiled or oleophilic nature, in the pulling process is easy to carry downhole to uphole in the original work surface, and environmental pollution caused by waste oil, thus
  • the use of steel wire for the manufacture of a flexible oil-impregnated rope is an important feature of the present invention.
  • the technique for manufacturing the oil wick of the present invention will be described in detail below.
  • Fig. 8 is a flow chart showing the manufacturing process of the sealing steel cord of the present invention.
  • a plurality of steel wire strands 84 are made into a steel rope by using a tanning machine 813, and a temperature-controlled pressing line die 815 is disposed at the junction point 84a of the tanning, and a temperature-injecting die 815 is provided with a injection hole 815b.
  • a filling machine 814 and the filling machine 814 is connected with the injection hole 815b, so that the filling machine 814 injects the filling into the tantalum junction point 84a through the injection hole 815b, and at the same time, through the temperature control pressing line
  • the heating body 815a on the mold 815 heats the junction point 84a, so that the filled filling material can reach a viscosity state, so that the filling material can fill the gap space inside the steel wire strand, thereby forming a sealing steel cord;
  • the tanning machine 813 can clamp a plurality of steel strands 84 around the communication cable to manufacture a wicking rope capable of transmitting electrical signals.
  • the obtained sealing steel cord is subjected to stress relief treatment by a stress relief device 816 to remove the processing stress inside the sealing steel cord, and the obtained sealing steel cord 83 is stored on the wire take-up machine 819.
  • the steel strand 84 used in the tanning of the steel rope is made of a plurality of steel wires 87, and is filled and heated at the junction of the tantalum, so that the filled filler 86 fills the internal gap space of the steel wire, thereby making the steel wire strand Form a sealed whole.
  • the filler 86 used in the present invention is a polymer or a rubber and a material having the same properties.
  • the sealing steel cord 83 obtained in the step 1 is passed through a braiding machine 822, and the knitting machine 822 woven a wire mesh on the outer surface of the sealing steel cord 83 to form a sealing steel cord with a wire mesh;
  • the sealing wire with the wire mesh is passed through the controllable heating box 823, and the control heating box 823 heats the wire-sealing sealing steel wire to soften the filler on the sealing steel wire;
  • the sealing steel wire obtained in the above step is subjected to the diameter reduction treatment by the roller type mesher 824, so that the wire mesh will be
  • the sealing steel cord is tightly packed and avoids a sudden change in the diameter of the steel cord caused by the internal filling filler.
  • the resulting sealed steel cord 826 with wire mesh is stored on the take-up machine 827.
  • the woven mesh mesh has a diamond shape with a long axis diagonal size of 7-9 mm, a woven wire mesh diameter of 0.6 mm to 1.4 mm, and a mesh layer of 1-3 layers.
  • the wire mesh of the wire mesh is made of a plurality of steel wires. When the wire is meshed, the wire strand is used according to the main gravity of the steel wire and the frequency of fishing. The number of roots is also different, choosing between 8 and 24 roots.
  • the outer protective seal layer in the present invention may be made of a polymer or a rubber material.
  • the wire-sealing sealing steel wire 826 prepared in the step 2 is pre-heat treated (not shown), so that the filling material on the sealing steel wire reaches a viscosity state, and the preheating temperature is based on the viscosity of the filling material.
  • the preheating temperature is based on the viscosity of the filling material.
  • the preheated steel rope is passed through an extruder 832, and the plasticized outer protective coating is applied on the outer surface of the wire mesh, so that the outer protective coating and the filler on the steel rope are melted into One body
  • the steel wire obtained in the previous step is cooled by the cold water tank 833, so that the outer protective coating and the filler are cooled to form an outer protective sealing layer, so that the steel cord 835 coated with the outer protective sealing layer is obtained, and is stored in the wire take-up machine. On 836.
  • the process flow chart is shown in FIG. 10b, and the preheated steel rope passes through the extruder 832, and the extruder 832 coats the plasticized outer protective coating on the rubber sheath. After the outer surface of the wire mesh is passed, the steel wire is entirely vulcanized by a vulcanization line 837, and the other processes are the same as those of the outer cover layer made of a polymer material.
  • FIG. 1 The calendering and sizing treatment process in the manufacturing method of the present invention is shown in FIG.
  • the steel cord 835 coated with the outer sealing layer prepared in the step 3 is subjected to heat treatment through the heating box 842, so that the outer protective sealing layer is brightened in a plasticized state;
  • the flexible drawstring 23 is manufactured, and its structural diagram is as shown in FIG.
  • the multi-strand conductor is coated with a layer of high temperature resistant outer insulating layer to form a communication wire.
  • the communication wire requires low resistivity, high temperature resistance of the outer sheath, high tensile strength, good fracture resistance, insulation during stretching, and reliable working stability.
  • the communication wire 89 prepared in step 1 is made into a communication cable strand 85, and the communication cable strand 85 is passed through the twisting machine 813, so that the communication cable strand 85 and the plurality of strands 84 are together.
  • the remaining process is the same as in Embodiment 1 to prepare a sealing steel cord 83a, and the communication cable strand 85 is located at the core of the sealing steel cord 83a.
  • the subsequent process is the same as in the first embodiment, so that the flexible wicking cord 23a having the communication function manufactured by the method of the present invention can be obtained, and its structural diagram is as shown in Fig. 12a.

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Abstract

一种智能卷扬式提拉采油系统及其抽油绳的制造方法被公开。卷扬式提拉采油系统包括:驱动总成(1),具有卷筒(11)以及驱动卷筒(11)转动的驱动装置(12);机架(2),其上安装有滑轮(21);抽油绳(23),一端缠绕在卷筒(11)上,另一端绕过滑轮(21)连接位于井下油井管柱(5)内的采油装置(4);控制装置(9),用于控制驱动装置(12)旋转;其中,采油装置(4)设有井下液柱高度检测器(6),井下液柱高度检测器(6)将检测到的液柱高度信号传输给控制装置,以便控制装置在收到预设液柱高度信号时,控制驱动装置(12)动作,从而带动采油装置(4)提拉油井管柱(5)内的液体到井口外。该采油系统采油效率高,降低了能耗,减少了设备磨损。

Description

卷扬式提拉采油系统及其抽油绳的制造方法 技术领域
本发明涉及一种采油设备, 尤其涉及一种卷扬式提拉采油设备及其抽油绳的制造方 法。 背景技术
目前, 在机械采油中普遍使用游梁式抽油机, 游梁式抽油机是井下抽油泵的底面动力 设备, 俗称磕头机, 它将抽油机悬点的往复运动通过抽油杆传递给井下柱塞泵, 抽油时, 电动机的传动经变速箱、 曲柄连杆结构变成驴头的上下运动, 驴头经光杆、 抽油杆带动井 下深井泵的柱塞作上下运动, 从而不断的把井中的石油或含油液体抽出井筒。
游梁式抽油机的这种采油方式适用于产油量大的油井, 游梁式抽油机能够快速的并且 不间断的将油井中的石油或含油液体抽出,但是对于产油量低的油井, 由于地层供油不足, 油井液面恢复缓慢, 采用游梁式抽油机进行采油时常出现干抽现象, 造成电能的损耗同时 也会对设备造成磨损。 如果要等待液面恢复后再抽油, 必需依靠人工控制抽油机启动和关 闭, 而人工控制抽油机启动和关闭的时间不易掌握, 人工控制抽油机启动和关闭的时间不 当容易造成卡井和作业返工; 同时由于抽油机一般设置在野外, 要求全天候不停的工作, 采用人工控制增加了作业成本, 给生产带来了不便。 并且, 游梁式抽油机结构复杂, 成本 高, 占地面积大, 在一些可用空间小的地方无法使用。
发明内容
本发明的目的就是为了克服上述现有技术存在的问题, 提供一种卷扬式提拉采油系 统, 采用控制装置与井下的检测装置相配合, 智能控制采油系统的工作和停止, 保证了每 次采油的油量, 避免了出现干抽现象, 同时提高了采油的效率, 又降低了能耗, 减少了设 备的磨损, 该智能卷扬式提拉采油系统结构设计简单, 占地面积小。
本发明的另一目的是提供一种适合于卷扬式提拉采油系统使用的抽油绳的制造方法, 用于制造不沾油的抽油绳, 从而防止普通钢丝绳索在提拉过程中将井下原油携带到井上作 业面的情况发生, 避免环境污染和原油浪费。
根据本发明的第一方面, 本发明的智能卷扬式提拉采油系统包括: 驱动总成, 具有 卷筒以及驱动卷筒转动的驱动装置; 机架, 安装在地面上, 其上安装有滑轮; 采油装置, 位于井下油井管柱内; 抽油绳, 一端缠绕在卷筒上, 另一端绕过滑轮连接采油装置; 控制 装置, 用于通过控制驱动装置旋转, 驱动卷筒正反转, 从而通过抽油绳带动采油装置进行 反复提拉采油操作, 其中, 所述采油装置设有井下液柱高度检测器, 用于在检测到井下采 集的液体到达设定液柱高度时, 使控制装置控制采油装置进行提拉采油操作。
其中, 所述井下液柱高度是指油井管柱内的液柱高度, 所述井下液柱高度检测器在检 测到井下采集的液体到达设定液柱高度时, 通过有线或无线传输方式将检测到的液柱高度 信号传输给所述控制装置, 以便控制装置在收到预期液柱高度信号时, 控制驱动装置驱动 卷筒转动, 再由卷筒驱动抽油绳带动采油装置把油井管柱中预设一定柱高的液体提拉到油 井外。
其中, 采油装置还设有用于提拉油井管柱中液体的能够扩张的抽子, 所述抽子中装有 一个或多个其直径小于油井管柱内径的硬质高分子材料胶筒, 所述在采油装置上行速度为 0.2m/S~1.2m/S时, 在上行的提拉力和油井管柱内液体重力作用下压缩, 所述胶筒直径扩张 为等于油井管柱内径。
特别是, 油井管柱采用多根油管连接而成, 并使得油管间连接缝隙小得足以使所述高 分子材料胶筒在油管内平稳滑行, 避免因缝隙过大而造成破损。 其中, 井下液柱高度检测器连接在抽油绳的所述另一端, 包括: 用于检测井下采集的 液体高度对应的压力的压力变送器, 具有测压孔, 压力变送器安置在由压力变送器外壳和 连接在压力变送器外壳上的密封钢体形成的空间内; 所述密封钢体上开有连接外界液体和 测压孔的传压孔, 以便将与油井管柱中液体高度对应的压力传递给压力变送器。
特别是, 所述密封钢体具有与外界油井管柱接触的导电接触部件; 所述压力变送器一 方面与所述抽油绳的金属芯电连接, 另一方面与所述压力变送器外壳电连接, 以便将检测 到的井下液柱的信号通过抽油绳和油井管柱传递给所述控制装置。
导电接触部件包括安置在密封钢体内的多对钢球, 多对钢球中的每一对沿径向放置, 并且两钢球由弹簧连接, 使得两钢球在弹簧作用下沿径向向外突出, 以便钢球接触所述油 井管柱的内壁。
特别是, 抽油绳具有两根通讯线缆, 所述压力变送器分别与两根通讯线缆电连接, 以 便将检测到的井下液柱的信号通过抽油绳的通讯线缆传递给所述控制装置。
特别是, 压力变送器具有无线发射单元, 压力变送器将检测到的井下液柱的信号通过 无线发射单元传递给所述控制装置。
其中, 油井管柱由多根油管通过接箍连接而成, 在相邻油管之间设置尼龙环, 或钢环 或位于接箍内壁上的凸起, 以便减小相邻油管之间的连接缝隙。
特别是, 尼龙内径或钢环内径与油管内径一致。
其中, 滑轮上还安装有深度速度检测装置, 所述驱动装置上还安装有编码器。
根据本发明的第二方面, 本发明的卷扬式提拉采油系统的抽油绳制造方法, 包括: 采用捻制设备将多根钢丝股捻制成密封钢绳;
在密封钢绳外表面编织捆绑钢绳的丝网;
在丝网外表面上涂覆外护密封层, 将丝网及密封钢绳封闭在其内。
其中, 所述捻制密封钢绳按如下方式制造:
(al )将多根钢丝股捻制成钢绳, 同时, 采用灌料机在钢丝股捻制的结交点灌料, 使得 灌注的填充物充满钢丝股内部缝隙空间, 形成密封钢绳;
(a2)将密封钢绳进行去应力处理, 以便去除密封钢绳的内部加工应力。
其中, 在所述结交点灌料的同时对结交点进行加热, 使得灌注的填充物达到粘溶状态, 以便充满钢丝股内部缝隙空间。
其中, 所述编织丝网按如下步骤制造:
( b 1 )采用编织机在所述密封钢绳的外表面上编织丝网;
(b2)采用可控加温箱对编织有丝网的密封钢绳加热, 使得密封钢绳上的填充物软化; (b3 )将带有丝网的密封钢绳进行缩径处理, 使得丝网将所述密封钢绳包裹紧实。 其中, 所述钢丝股和所述丝网的网丝股分别采用多根钢丝捻制而成, 在钢丝捻制的结 交点处灌料, 使得灌注的填充物充满钢丝内部缝隙空间。
其中, 所述涂覆外护密封层包括以下步骤:
(cl )对裹有丝网的密封钢绳进行预热处理, 使得密封钢绳上的填充物达到粘溶状态; (c2)将塑化好的外护涂料涂覆在外表面上,使得外护涂料与所述填充物融为一体,形 成外护密封层。
其中, 上述方法还包括对所述涂覆有外护密封层的钢绳依次进行如下处理:
(dl )将所述涂覆有外护密封层的钢绳进行加热, 使得外护密封层达到塑化状态; (d2 )钢绳整体通过定径模进行压光定径处理, 使所述钢绳整体外表面光滑, 直径统 其中, 在制造密封钢绳时, 多根钢丝股围绕通讯线缆捻制。
本发明的有益效果体现在以下方面:
1、 由于采用了井下液柱高度检测器检测所采集的原油的柱高, 并在柱高度达到设定 柱高时, 控制装置才控制驱动装置提拉油井管柱内的原油, 可随意设置抽油柱高, 可实现 智能控制, 从而可以提高采油效率, 减少无用功, 同时又节约了电力;
2、 通过检测每次所采集的原油的柱高, 可以准确的计算原油的产量, 实现标准计量; 并且通过井下液柱高度检测器所检测到的压力的变化, 可以实现液面的实时测量;
3、 压力变送器与控制装置之间通过抽油绳的金属芯和油井管柱, 或者通过在抽油绳 内设置通讯线缆, 或者通过无线发射单元实现信号的传递, 而压力变送器与油井管柱之间 又通过钢球实现连接, 结构设计简单可靠;
4、 采用抽油绳代替抽油杆, 负荷小, 可配置小功率电机, 节省电能;
5、 油井管柱之间采用最小缝隙连接, 可以减少油管间隙大对采油装置的胶筒的损伤, 不仅可以延长胶筒的寿命, 同时也有利于提高采油效率, 减小磨耗内层底部形式;
6、 由于采油装置在提拉过程中, 从井底到井口运行, 冲程长, 提高产量, 有利于原 油的汇集及负压解堵;
7、 采油卷筒缠绕抽油绳作为采油的动力装置, 结构设计更简单, 占地面积小, 成本 低;一胶筒上行时在油井管柱内壁密封滑动, 漏失小, 泵效高, 减少大量无用功, 抽汲效率 大幅提高。 附图说明
图 1是本发明智能卷扬式提拉采油系统的整体结构示意图;
图 2是本发明智能卷扬式提拉采油系统驱动总成的侧视示意图;
图 3是本发明智能卷扬式提拉采油系统排绳装置的主视示意图;
图 3a是排绳装置的侧视示意图;
图 3b是排绳装置的俯视示意图;
图 3c是排绳装置的工作原理示意图;
图 4 是本发明智能卷扬式提拉采油系统井下液柱高度检测器第一实施例的结构示意 图;
图 4a是本发明智能卷扬式提拉采油系统井下液柱高度检测器第二实施例的结构示意 图;
图 4b是本发明智能卷扬式提拉采油系统井下液柱高度检测器第三实施例的结构示意 图;
图 5是本发明智能卷扬式提拉采油系统抽子的结构示意图;
图 6是本发明智能卷扬式提拉采油系统油井管柱连接第一实施例的结构示意图; 图 6a是本发明智能卷扬式提拉采油系统油井管柱连接第二实施例的结构示意图; 图 6b是本发明智能卷扬式提拉采油系统油井管柱连接第三实施例的结构示意图; 图 7是本发明的控制装置的控制原理图;
图 8、 8a是本发明柔性抽油绳的制造方法中密封钢绳的生产工艺流程图;
图 9是对密封钢绳编织丝网的工艺流程图;
图 10a、10b是对图 9中生产的带有丝网的密封钢绳外表面涂覆外护密封层的工艺流程 图;
图 11是对由上述工艺制得的抽油绳进行压光定径处理的工艺流程图;
图 12、 12 a是采用本发明的方法制造的抽油绳的截面示意图。
附图标记说明: 1-驱动总成; 2-机架; 3-排绳装置; 4-采油装置; 5、 5a、 5b-油井管柱; 6-井下液柱高度检测器; 7-抽子; 8-加重杆; 9-控制装置;
10-基座; 11-卷筒; 11a-卷同轴; 110-被动轮; 111-卷筒链轮; 12-电机; 12a-编码器; 120-主动轮; 13-链带; 14-过渡链条; 15-传动链条; 18-液力推力器; 18a-制动器; 18b-配 重; 18c-刹车带; 21-滑轮; 21a-深度速度检测装置; 23-抽油绳; 23a-绳头压绳板; 23b-通讯线缆;
30-竖直支架; 30a-7j平支架; 30b水平导轨; 31-排绳链条; 31a-滑块; 32-滑板; 32a- 定位槽; 32b-支板; 33-滚轮; 34-排绳立辊; 34a-限位轮; 35-传动大链轮; 35a-传动轴; 35b- 传动小链轮; 36-排绳链轮; 36a-驱动轴; 37-张紧轮; 38a-主动锥齿轮; 38b-被动锥齿轮; 39a、 39b-链轮轴; 39、 39,-链轮;
41-防喷盒; 42-采油树; 42a-单流阀; 43-进油管线;
51-接箍; 52-凸起; 53-尼龙环; 53,-钢环;
60-打捞头; 61-连接套; 61a-密封圈; 62-压力变送器; 62a-测压孔; 62b-压力变送器外 壳; 62c-绝缘套; 62d-无线发射单元; 63-密封钢体; 63a-传压孔; 63b-钢球; 63c-弹簧; 64- 快速接头; 64a-圆筒形结构; 64b-圆孔; 64c-条形孔;
70、 中心管; 71-上接头; 71a-圆形凸头; 71b-圆柱形顶部; 71c-圆筒形底部; 71d-进 油孔; 72-下接头; 72a-圆形凸头; 72b-圆柱形顶部; 72c-圆筒形底部; 72d-进油孔; 73-凡 尔球; 74a-背帽; 74b-压帽; 75-进压块; 75a-进压孔; 76a、 76b-硬质高分子材料胶筒; 77- 连接块;
81-外护密封层; 82-丝网、 83、 83a-密封钢绳; 84-钢丝股; 84a-结交点; 85-通信线缆 股; 86-填充物; 87-钢丝; 23、 23a-抽油绳; 89-通信导线; 811-放线机; 812-通信导线; 813- 捻制机; 814-灌料机; 815-温控压线模; 815a-加热体; 815b-注料孔; 816-去应力器; 817- 牵引机; 819-收线机;
821-放线机; 822-编织机; 823-可控加温箱; 824-滚轮式紧网器; 825-牵引机; 826-带 有丝网的密封钢绳; 827-收线机;
831-放线机; 832-挤出机; 833-冷水槽; 834-牵引机; 835-涂有外护密封层的钢绳; 836- 收线机; 837-硫化线;
841-放线机; 842-加热箱; 843-温控定径模; 844-冷水槽; 845-牵引机; 847-收线机。 具体实施方式
如图 1本发明智能卷扬式提拉采油系统的整体结构示意图所示, 本发明的智能卷扬式 提拉采油系统包括: 设置在地面基座 10上的驱动总成 1, 具有用于缠绕抽油绳 23的卷筒 11和驱动卷筒 11转动的电机 12; 安装在地面上的机架 2, 其上安装有滑轮 21 ; 安置在井 下油井管柱 5内的采油装置 4;抽油绳 23, 一端缠绕在卷筒 11上, 另一端绕过机架 2上的 滑轮 21与采油装置 4连接; 控制装置 9, 用于通过控制电机 12旋转, 驱动卷筒 11转动, 从而通过抽油绳 23带动采油装置 4进行提拉采油操作。 其中, 所述采油装置 4设有井下 液柱高度检测器 6, 用于在检测到井下采集的液体到达设定液柱高度时, 使所述控制装置 9控制所述采油装置 4进行提拉操作。
具体地说, 井下液柱高度检测器 6在检测到井下采集的液体到达设定液柱高度时, 通 过有线或无线传输方式将检测到的液柱高度信号传输给控制装置, 以便控制装置 9在收到 预期液柱高度信号时, 控制电机 12驱动卷筒 11转动, 再由卷筒 11驱动抽油绳 23带动采 油装置 4提拉油井管柱 5中预期柱高的石油或含油液体到油井外。
采油装置 4还设有用于提拉油井管柱 5中石油或含油液体的抽子 7 (如图 5所示),抽 子 7中装有一个或多个其直径小于油井管柱内径的硬质高分子材料胶筒 76a、 76b, 硬质高 分子材料胶筒 76a、 76b在采油装置 4上行速度为 0.2 m/s~1.2 m/s时,在上行的提拉力和油 井管柱 5中石油或含油液体重力作用下压缩, 使其直径变为等于油井管柱内径。
如图 1所示, 油井管柱 5直接与地面的采油树 42连接, 采油树 42通过单流阀 42a与 进油管线 43连接, 采油树 42的上方设置有防喷盒 41, 以防抽油绳 23上行时, 在抽油绳 露出采油树 42 时粘附在抽油绳上的石油或含油液体四处飞溅, 造成石油或含油液体的浪 费。 抽油绳 23依次穿过防喷盒 41、 采油树 42与油井管柱 5内的采油装置连接, 抽油绳 23带动采油装置 4在油井管柱 5内上行时,从而将油井管柱 5内的石油或含油液体向上提 起, 石油或含油液体由油井管柱 5内上升至采油树 42, 再由采油树 42流入进油管线 43, 石油或含油液体得到收集。
如图 2本发明智能卷扬式提拉采油系统驱动总成的侧视示意图所示,卷筒 11通过卷筒 轴 11a安装在基座 10上, 卷筒 11可随卷筒轴 11a—起相对基座 10转动, 卷筒轴 11a的一 侧安装有被动轮 110, 电机 12的输出轴上安装有主动轮 120, 如图 1所示, 主动轮 120与 被动轮 110之间通过链带 13连接,使得电机 12转动时,电机输出轴带动主动轮 120转动, 主动轮 12通过链带 13带动被动轮 110转动, 由于被动轮 110与卷筒 11同轴, 被动轮 110 转动便带动卷同轴 11a转动,从而带动卷筒 11转动,卷筒 11便进行缠绕抽油绳 23的动作, 使得抽油绳 23带动采油装置 4上行进行采油工作。
本发明的驱动总成 1还具有排绳装置 3, 排绳装置 3安置在卷筒 11与滑轮 21之间。 如图 3、 3a所示, 排绳装置 3具有安装在基座 10上位于前后两侧的竖直支架 30, 两竖直 支架 30的下端由水平支架 30a连接,上端由水平导轨 30b连接,水平导轨 30b由相对放置 的两槽钢形成, 两槽钢之间相隔一定的距离, 如图 3所示。 如图 3a所示, 水平支架 30a 的左端安装有传动大链轮 35, 传动大链轮 35通过传动轴 35a安装在水平支架上 30a上, 传动轴 35a上位于传动大链轮 35的外侧安装有传动小链轮 35b, 竖直支架 30的上端位于 水平导轨 30b的下方安装有排绳链轮 36, 排绳链轮 36通过驱动轴 36a安装在竖直支架 30 上,排绳链轮 36与传动小链轮 35b之间还设置有张紧轮 37,并且排绳链轮 36、张紧轮 37、 传动大链轮 35、 传动小链轮 35b都位于左侧竖直支架 30的外侧, 同时排绳链轮 36、 张紧 轮 37、 传动小链轮 35b位于同一平面内, 排绳链轮 36与传动小链轮 35b之间通过传动链 条 15连接, 张紧轮 37张紧在传动链条 15上, 如图 3所示。 卷同轴 11a上位于被动轮 110 的外侧还安装有卷筒链轮 111, 如图 2所示, 并且卷筒链轮 111与传动大链轮 35位于同 一平面内, 卷筒链轮 111与传动大链轮 35之间通过过渡链条 14连接(如图 1所示)。
如图 1所示, 当电机 12转动带动卷筒轴 11a转动时, 安装在卷筒轴 11a上的卷筒 11 转动带动抽油绳 23向上提拉采油装置 4的同时,安装在卷同轴 11a上的卷筒链轮 111也转 动, 卷筒链轮 111通过过渡链条 14带动传动大链轮 35转动, 由于传动小链轮 35b与传动 大链轮 35同轴, 因此传动大链轮 35转动也带动传动小链轮 35b转动, 传动小链轮 35b通 过传动链条 15带动排绳链轮 36转动, 这样便实现了卷筒的转动向排绳装置 3的传递。
再如图 3a、 3b所示, 排绳链轮 36通过驱动轴 36a安装在竖直支架 30上, 驱动轴 36a 上位于竖直支架 30的内侧安装有主动锥齿轮 38a;水平导轨 30b的底部左右两侧分别向下 伸出两支耳, 两支耳上分别安装有链轮轴 39a、 39b, 两链轮轴 39a、 39b刚好与驱动轴 36a 等高, 两链轮轴 39a、 39b的两端分别安装有一对链轮 39、 39', 其中左侧链轮轴 39a上的 一对链轮 39分别通过螺栓固定在链轮轴 39a上, 使得一对链轮 39同时随链轮轴 39a—起 相对支耳转动; 右侧链轮轴 39b上的一对链轮 39'分别通过轴承安装在链轮轴 39b上, 而 右侧链轮轴 39b固定在右侧支耳上, 使得一对链轮 39'可分别相对右侧链轮轴 39b转动。 右侧一对链轮 39与左侧一对链轮 39'分别通过两条排绳链条 31连接(图 3a中只示出其中 一条排绳链条 31 )。 如图 3b所示, 左侧链轮轴 39a上位于一对链轮 39之间安装有被动锥 齿轮 38b, 被动锥齿轮 38b刚好与主动锥齿轮 38a啮合, 当排绳链轮 36转动时, 便可带动 与其同轴的主动锥齿轮 38a转动,继而带动与主动锥齿轮 38a啮合的被动锥齿轮 38b转动, 由于被动锥齿轮 38b安装在左侧链轮轴 39a上, 被动锥齿轮 38b转动带动左侧链轮轴 39a 转动, 从而带动安装在左侧链轮轴 39a上的一对链轮 39转动, 于是左侧的一对链轮 39便 通过两根排绳链条 31带动右侧的一对链轮 39'转动, 这样便使得两根排绳链条在左、 右侧 链轮 39、 39'之间循环移动。
如图 3a所示,水平导轨 30b上还设置有滑动小车,包括位于水平导轨 30b前后两侧的 两滑板 32, 两滑板 32在水平导轨 30b的顶部通过螺栓彼此连接, 这样使得两滑板 32横跨 在水平导轨 30b上, 使得两根排绳链条 31分别位于两滑板 32的内侧, 两滑板 32分别由 水平导轨 30b的顶部延伸至排绳链条的下排, 两滑板 32上分别设置有定位槽 32a, 定位槽 32a由排绳链条的下排延伸至排绳链条的上排, 并且排绳链条 31上固定有滑块 31a, 滑块 31a向外伸出穿过滑板 32上的定位槽 32a, 从而将滑板 32与排绳链条 31连接。两滑板 32 之间由顶部向下伸出一支板 32b, 支板 32b刚好位于形成水平导轨 30b的两槽钢之间, 如 图 3b所示, 支板 32b的前后两端分别布置有一排滚轮 33, 每一排包含有三个滚轮, 每个 滚轮各自通过一个销轴与支板 32b固定连接, 使得两排滚轮刚好分别位于两个槽钢内, 图 3b中为了清除显示支板 32b与滚轮的连接省去了滑板 32及其顶部的部分。 每一排滚轮位 于中间的一个滚轮的高度高于其它两个滚轮(如图 3a所示), 使得中间的滚轮顶住槽钢的 顶板, 其它两个滚轮压住槽钢的底板, 如图 3所示, 图 3中为了清楚显示水平导轨 30b的 结构省去了滚轮 33及支板 32b的结构。
如图 3a所示, 两滑板 32的顶部还并列安装有两排绳立辊 34, 两排绳立辊 34之间具 有一定的间隙, 抽油绳 23从两排绳立辊 34之间穿过, 两排绳立辊 34的顶部各伸出一支 板, 支板上通过销轴安装有限位轮 34a, 以便保证抽油绳 23始终位于两排绳立辊 34之间。
如图 3a所示, 当两排绳链条 31在左、 右侧链轮 39、 39'之间循环移动时, 便会带动 通过滑块 31a与排绳链条 31连接的滑板 32移动, 这样便会使得整个滑动小车通过两排滚 轮 33在水平导轨 30b内左右行走移动, 夹在两排绳立辊 34之间的抽油绳 23便会随之左 右移动。
左、 右侧链轮 39、 39'之间的距离应与卷筒 11的长度相等, 以确保滑动小车从左向右 移动一次抽油绳 23刚好在卷筒 11上均匀缠绕一层。
如图 3c排绳装置的工作原理结构图所示, 抽油绳 23位于卷筒 11的右端 (图 3c中从 右向左看) 时, 此时滑动小车也位于水平导轨 30b的右端, 电机 12工作带动卷筒 11转动 进行缠绕抽油绳 23的工作时,同时也带动排绳链条 31移动,使得滑动小车在水平导轨 30b 上从右向左移动, 使得夹在两排绳立辊 34之间的抽油绳 23也随滑动小车一起从右向左移 动, 这样抽油绳 23便会在卷筒 11上从右向左逐渐缠绕; 当滑动小车移动到排绳链条 31 的最左端时,此时抽油绳 23也刚好缠绕到卷筒 11的最左端,完成了在卷筒 11上一层的缠 绕, 如图 3a所示, 由于此时排绳链条 31还会继续循环移动, 此时排绳链条 31上的滑块 31a从下排排绳链条移动到上排排绳链条, 而滑板 32不能上下移动, 因此滑块 31a只能在 定位槽 32a由下向上移动到达定位槽 32a的顶部,这样,滑块 31a便会随着排绳链条 31的 移动又带着整个滑动小车在水平导轨 30b上从左向右移动, 夹在两排绳立辊 34之间的抽 油绳 23也随滑动小车一起从左向右移动,这样抽油绳 23便又在卷筒 11上从左向右逐渐缠 绕, 进行第二层的缠绕, 依次进行下去, 直到电机 11停止工作, 卷筒 11停止转动。
卷筒 11排放抽油绳 23的原理与上述缠绕抽油绳的原理相同, 在此不再重述。
如图 1所示本发明智能卷扬式提拉采油系统的采油装置 4包括从上往下依次连接的井 下液柱高度检测器 6、抽子 7和加重杆 8。下面结合附图 4、 4a、 4b详细描述本发明的井下 液柱高度检测器的结构。
如图 4为本发明的井下液柱高度检测器 6第一种结构的示意图。 如图 4所示, 本发明 的井下液柱高度检测器 6包括从上往下布置并依次通过螺纹连接的打捞头 60、 连接套 61、 压力变送器外壳 62b和密封钢体 63, 打捞头 60、 连接套 61、 压力变送器外壳 62b均具有 内腔, 压力变送器外壳 62b的内腔内安置有压力变送器 62, 抽油绳 23外包裹有绝缘层, 抽油绳 23依次穿过打捞头 60和连接套 61的内腔, 在压力变送器外壳 62b的内腔内与压 力变送器外壳 62b连接, 压力变送器 62—方面与抽油绳 23的金属芯电连接, 另一方面又 通过压力变送器外壳 62b和密封钢体 63, 以及密封钢体 63上的导电接触部件与油管 5实 现电连接。
连接套 61的内腔的顶部设置有密封圈 61a, 密封圈 61a套装在抽油绳 23上, 当将连 接套 61拧紧在打捞头 60的下端时, 在打捞头 60和连接套 61的挤压作用下, 密封圈 61a 膨胀, 使得密封圈 61a与抽油绳 23和连接套 61都紧密结合, 油管 5内的石油或含油液体 不会由打捞头 60与抽油绳之间的缝隙进入连接套 61的内腔。
压力变送器外壳 62b的内腔的上端设置有绝缘套 62c,抽油绳 23的端头穿过绝缘套 62c 并连接有绳头压绳板 23a, 以便将抽油绳 23的端头锁死在绝缘套 62c内, 当抽油绳 23上 行时,其端头不会从绝缘套 62c内脱出,从而实现抽油绳 23与压力变送器外壳 62b的连接。
密封钢体 63密封在压力变送器外壳 62b的底部, 将压力变送器 62密封在压力变送器 外壳 62b的内腔内, 压力变送器 62的底部设有测压孔 62a, 密封钢体 63上开设有联通油 井管柱 5内石油或含油液体和测压孔 62a的传压孔 63a, 以便油井管柱 5内液体的压力通 过传压孔 63a传递给压力变送器 62的测压孔 62a, 压力变送器 62的底部与压力变送器外 壳 62b的内壁之间设置有密封圈, 以便当油井管柱 5内的液体由传压孔 63a传递到压力变 送器 62的测压孔 62a时, 液体不会进入压力变送器外壳 62b的内腔内。 密封钢体 63上还 设置有导电接触部件, 包括多对钢球 63b, 多对钢球中的每一对沿径向布置, 并且两钢球 之间由弹簧 63c连接, 两钢球在弹簧 63c的作用下沿径向向外突出, 使得钢球接触到油井 管柱 5的内壁。压力变送器 62还与压力变送器外壳 62b电连接, 由于压力变送器外壳 62b 与密封钢体 63螺纹连接, 密封钢体 63又通过钢球 63b与油井管柱 5接触, 因此压力变送 器 62测得的井下液柱高度对应的液体压力信号便可分别通过抽油绳 23和油井管柱 5传递 到地面的控制装置 9, 当控制装置 9接收到预期的液柱高度对应的压力信号时便控制电机 12工作, 从而带动卷筒 11进行缠绕抽油绳 23的动作, 使得抽油绳 23向上提拉采油装置, 进行采油工作。
可以在密封钢体 63上设置多组导电接触部件, 如图 4中导电接触部件为上下布置的 两组, 以保证井下液柱高度检测器 6在随抽油绳 23—起上行的过程中, 导电接触部件中 始终有钢球与油井管柱 5的内壁接触, 从而保证井下液体的压力信号能够顺利的传递到地 面。
图 4a是为本发明的井下液柱高度检测器 6第二种结构的示意图。 如图 4a所示, 本发 明的抽油绳 23外包裹有绝缘层, 内部具有两根通讯线缆 23b, 抽油绳 23通过两根通讯线 缆 23b与压力变送器 62电连接, 以便将压力变送器 62测得的井下液柱高度对应的的压力 信号传递到地面的控制装置 9, 当控制装置 9接收到预期的液柱高度对应的压力信号时控 制电机工作,从而带动卷筒 11进行缠绕抽油绳 23的动作,使得抽油绳 23向上提拉采油装 置, 进行采油工作。
井下液柱高度检测器 6的其它结构与第一种结构相同, 在此不再重述。
图 4b是为本发明的井下液柱高度检测器 6第三种结构的示意图。 如图 4b所示, 本发 明压力变送器外壳 62b的内腔内安置有压力变送器 62, 压力变送器 62具有无线发射单元 62d, 抽油绳 23外包裹有绝缘层, 抽油绳 23依次穿过打捞头 60和连接套 61的内腔以及 压力变送器外壳 62b的顶部与压力变送器 62连接。 压力变送器 62测得的井下液柱高度对 应的压力信号通过无线发射单元 62d传递到地面的控制装置 9, 当控制装置 9接收到预期 的液柱高度对应的压力信号时控制电机工作,从而带动卷筒 11进行缠绕抽油绳 23的动作, 使得抽油绳 23向上提拉采油装置, 进行采油工作。
井下液柱高度检测器 6的其它结构与第一种结构相同, 在此不再重述。
如图 4、 4a、 4b所示密封钢体 63的底部设置有快速接头 64, 快速接头 64具有圆筒形 结构 64a, 圆筒形结构 64a的侧壁上开设有圆孔 64b, 圆孔 64b的底部开有条形孔 64c。 如 图 5所示为本发明的抽子 7的结构示意图,抽子 7包括中心管 70, 中心管 60的上端通过 螺纹连接有上接头 71, 下端通过螺纹连接有下接头 72, 上接头 71具有圆筒形底部 71c和 圆柱形顶部 71b, 圆柱形顶部 71b的直径与条形孔 64c的宽度相同, 圆柱形顶部 71b的上 端设置有圆形凸头 71a, 凸头 71a的直径与圆孔 64b的直径相同, 将圆形凸头 71a卡入快 速接头 64的圆孔 64b内, 将圆柱形顶部 71b卡入条形孔 64c内, 从而将上接头 71与密封 钢体 64快速连接, 以便实现抽子 7与井下液柱高度检测器 6的连接。
上接头 71的圆筒形底部 71c的底端通过螺纹拧紧在中心管 70上,上接头 71的圆筒形 底部 71c的上端圆周壁上开设有多个进液孔 71d, 外界液体可由进液孔 71d进入圆筒形底 部 71c内。
下接头 72的结构与上接头 71相同,下接头 72倒置,其圆筒形底部 72c的底端通过螺 纹拧紧在中心管 70的底部; 下接头 72用于实现抽子 7与加重杆 8的快速连接。
中心管 70的顶部放置有凡尔球 73, 凡尔球 73将中心管 70的顶端密封。
如图 5所示, 中心管 70上位于上接头 71的底部通过螺纹安装有背帽 74a, 背帽 74a 紧紧在抵靠在上接头 71的底部,背帽 74a紧紧在抵靠在上接头 71的底部; 中心管 70上位 于下接头 72的顶部通过螺纹安装有压帽 74b, 压帽 74b紧紧在挤压在下接头 71的圆筒形 底部 72c上, 以防止抽子在随抽油绳 23上行或下行时, 上接头 71和下接头 72与中心管 70之间的螺纹连接松开。
中心管 70上位于背帽 74a的下方套装有进压块 75, 进压块 75的内壁与中心管 70的 外壁之间具有一定的间隙, 进压块 75上开设有由进压块 75外壁延伸至进压块 75内壁的 进压孔 75a;中心管 70上位于进压块 75与压帽 74b之间套装有两硬质高分子材料胶筒 76a、 76b, 中心管 70上位于两硬质高分子材料胶筒 76a、 76b之间还套装有连接块 77, 两硬质 高分子材料胶筒 76a、76b以及连接块 77的内壁与中心管 70的外壁之间也具有一定的间隙, 使得外界液体可以由进压块 75上的进压孔 75a进入进压块 75的内壁与中心管 70的外壁之 间的间隙, 从而进入两硬质高分子材料胶筒 76a、 76b以及连接块 77的内壁与中心管 70 的外壁之间的间隙。
如图 5所示, 当抽子 7在抽油绳 23的提拉作用下随井下液柱高度检测器 6—起上行 时, 凡尔球 73在液体向下的作用下抵靠在中心管 70的顶端, 将中心管 70的顶端封闭, 外界液体不会由进液孔 71d进入中心管 70内, 而只能由进压块 75上的进压孔 75a进入两 硬质高分子材料胶筒 76a、 76b以及连接块 77的内壁与中心管 70外壁之间的间隙内,当抽 子上行速度达到 0.2m/s~1.2m/s 时, 本发明中优选抽子上行速度达到 0.6m/s以上时, 进入 两硬质高分子材料胶筒 76a、76b以及连接块 77的内壁与中心管 70外壁之间的间隙内的液 体对硬质高分子材料胶筒 76a、 76b产生强大的压力作用,使得两硬质高分子材料胶筒 76a、 76b向外膨胀变形, 膨胀后的硬质高分子材料胶筒 76a、 76b外壁与油井管柱 5的内壁相接 触, 将油井管柱 5内位于硬质高分子材料胶筒以上的液柱封堵在硬质高分子材料胶筒的上 方, 这样, 当硬质高分子材料胶筒随抽子一起向上移动时, 便将封堵在硬质高分子材料胶 筒上方的液体向上提起, 直至液体上行进入采油树 42内, 之后由采油树 42进入进油管线 43得到收集, 这样便完成了一次采油工作。
当抽子 7随抽油绳 23—起下行时, 油井管柱 5内的液体由下接头 72的进液孔 72d进 入中心管 70, 并随抽子的下行液体在中心管 70内向上移动, 封闭在中心管 70顶端的凡 尔球 73在液体向上的作用下漂起离开中心管 70的顶端, 使得中心管 70的顶部打开, 液 体由中心管顶部再经上接头 71的进油孔 71d流出,这样液体就不会由进压孔 75a进入两硬 质高分子材料胶筒 76a、 76b以及连接块 77的内壁与中心管 70外壁之间的间隙内,不对两 硬质高分子材料胶筒 76a、 76b产生压力, 因而两硬质高分子材料胶筒 76a、 76b不会膨胀, 使得硬质高分子材料胶筒与油井管柱 5的内壁之间相隔一定的距离, 抽子下行通畅。
本发明的油井管柱 5为消除了连接缝隙的油管。 油井管柱 5 由多节油管通过接箍 51 连接而成, 如图 6所示, 相邻油管 5a、 5b之间放置有尼龙环 53, 尼龙环 53的内径与相邻 两油管 5a、 5b的内径相同, 尼龙环 53的外径大于相邻两油管 5a、 5b的外径, 在两油管 5a、 5b的相邻的两端部外拧上接箍 51, 从而将两油管 5a、 5b紧紧的连接在一起, 以便减 小相邻两油管 5a、 5b之间的连接缝隙。 也可以在相邻油管 5a、 5b之间放置钢环 53', 如图 6a所示, 钢环 53'的内径与相邻两 油管 5a、 5b的内径相同, 钢环 53'的外径小于相邻两油管 5a、 5b的外径, 在两油管 5a、 5b的相邻的两端部外拧上接箍 51, 从而将两油管 5a、 5b紧紧的连接在一起, 以便减小相 邻两油管 5a、 5b之间的连接缝隙。
还可以在接箍 51内壁上设置一圈凸起 52, 如图 6b所示, 凸起 52的上下端面的形状 与两油管 5a、 5b的相邻的两端部的形状相匹配,将接箍 51拧在两油管 5a、 5b的相邻的两 端部外时, 使得凸起 52刚好卡在两油管 5a、 5b的相邻的两端部之间, 从而将两油管 5a、 5b紧紧的连接在一起, 以便减小相邻两油管 5a、 5b之间的连接缝隙。
另外,本发明的智能卷扬式提拉采油系统在滑轮 21上还设置有深度速度检测装置 21a, 如图 1所示,深度速度检测装置 21a与控制装置 9相连,用于检测滑轮 21转过的圈数, 从 而计算出抽油绳 23下行或上行的深度, 并将信号传递给控制装置 9。
电机 12上还设置有编码器 12a, 如图 1所示, 用于计算电机 12的转速, 以便计算出 抽油绳 23上行或下行的深度。
当根据编码器 12a计算得出的抽油绳 23上行或下行的深度值与根据深度速度检测装置 21a计算得出的抽油绳 23上行或下行的深度值不同时, 便可得知滑轮 21处于非正常工作 状态, 这时便可提醒工作人员对滑轮 21进行检查; 当根据两装置计算得出的抽油绳 23上 行或下行的深度值相同时, 滑轮 21处于正常工作状态。
再如图 1所示, 地面的基座 10上还设置有制动装置, 包括与控制装置 9连接的液力 推力器 18,与液力推力器 18输出轴连接的制动器 18a,制动器 18a上设置有配重 18b以及 与被动轮 110接触的刹车带 18c。
图 7显示了本发明的控制装置 9的原理, 该控制装置由可编程虚控制器或微处理器构 成,接收井下液柱高度检测器发送的井下压力检测信号,将井下压力值换算成液柱高度值, 并当液柱高度值大于或等于预先设置的预期液柱高度值时, 通过软起动器启动减速电机转 动, 从而驱动卷筒旋转, 使缠绕在卷筒上的抽油绳上行运动, 提拉预期液柱高度的原油或 含油液体。
此外, 可编程序控制器还通过接收来自深度速度检测器的采油装置 4的深度及上下行 速度信号, 控制采油装置 4的位置。 深度检测器可以安装在井架大滑轮的侧面, 通过对大 滑轮转动圈数进行计数, 计算连接采油装置 4的抽油绳下行的深度和速度。
此外, 可编程序控制器还连接用来输入控制信号的控制按钮, 并且还连接用于显示诸 如液柱高度信息、 深度 /速度信息的液晶显示屏。
另外, 可编程序控制器还连接用于提供减速电机转速的编码器, 由此算出滚筒转动情 况, 并可以利用滚筒转动情况确定滑轮正常转动的圈数, 由此检测出滑轮打滑等故障, 并 在滑轮出现此故障时, 进行停机操作。
如图 7所示, 可编程序控制器还连接用于刹车的制动器和用于检测减速电机运行电流 的电流互感器, 并在检测到减速电机电流过大或过载时, 进行停机操作。
如图 7所示, 可编程序控制器还连接用于与维护 /管理中心通信的远程移动通讯单元, 可以将采油量等运行信息和诸如减速电机电流过大或过载、 滑轮打滑等故障信息通知维护 /管理中心。
下面结合附图 1描述本发明的智能卷扬式提拉采油系统的工作原理。
首先, 液力推力器 18加载, 使得制动器 18a带动刹车带 18c与被动轮 110脱离, 电机
12启动, 带动卷筒 11进行排放抽油绳的工作, 抽油绳 23在加重杆 8及电机 12的作用下 下行, 采油装置 4在油井管柱 5内下行。
当抽子 7到达液面时, 压力变送器 62将检测到的井下压力的变化传递给控制装置 9, 控制装置 9判断出抽子 7已到达液面, 此点为液面深度, 这样便可实现液面的实时检测。 抽子 7继续下行,当滑轮 21上的深度速度检测装置 21a检测到抽子 7下行还未到达设置抽 吸深度, 而压力变送器 62检测到抽子以上的液柱高度已经到达设置抽吸高度时, 控制装 置 9控制电机 12反向转动, 带动卷筒 11也反向转动进行缠绕抽油绳的动作, 抽油绳 23 下行停止转为上行抽油;而当滑轮 21上的深度速度检测装置 21a检测到抽子 7下行至所设 置的抽吸深度, 但压力变送器 62检测到抽子 7上方的液柱高度还未到达设置的抽吸高度 时,控制装置 9便控制电机 12停止转动,液力推力器 18卸载,使得制动器 18a在配重 18b 的作用下带动刹车带 18c与被动轮 110接触, 被动轮 110制动, 卷筒 11停止转动, 抽油绳 23停止下行, 等待油井管柱 5内的液面恢复, 直至压力变送器 62检测到抽子 7以上的液 柱高度达到设置抽吸高度,控制装置 9控制液力推力器 18加载,使得制动器 18a带动刹车 带 18c与被动轮 110脱离, 电机 12启动进行反向转动, 带动卷筒 11也反向转动进行缠绕 抽油绳的动作, 抽油绳 23下行停止转为上行抽油。
当采油装置 4在抽油绳 23的带动下上行抽油时, 抽子 7以上的液柱在硬质高分子材 料胶筒 76a、 76b在作用下上行直至采油装置 4达到油井管柱 5的顶部,抽子 7以上的液柱 进入采油树 42, 这样便完成了一次抽油工作。 此时滑轮 21上的深度速度检测装置 21a检 测到抽油绳 23上行深度已达到保险值, 深度速度检测装置 21a将信号传递给控制装置 9, 控制装置 9控制电机 12又换向转动, 卷筒 11又进行排放抽油绳 23的工作, 抽油绳 23在 加重杆 8及电机 12的作用下又下行, 采油装置 4在油井管柱 5内下行, 进行下一次抽油 工作。
通过检测抽子每次抽吸的液柱的高度可以计量出原油的总产量, 实现原油产量的标准
S本发明抽油绳 23 为柔性的不沾油绳索, 由于钢丝绳索具有沾油或亲油性质, 容易在 提拉过程中将井下原有携带到井上作业面, 造成环境污染和原油浪费, 因此利用钢丝制造 柔性的不沾油绳索是本发明的一个重要特点, 下面详细说明本发明的抽油绳制造技术。 实施例 1
1、 密封钢绳的制造
如图 8本发明的密封钢绳的制造工艺流程图所示。
首先,采用捻制机 813将多根钢丝股 84捻制成钢绳,在捻制的结交点 84a处设有温控 压线模 815, 温控压线模 815上设有注料孔 815b, 其上方设有灌料机 814, 灌料机 814与 注料孔 815b相连,以便灌料机 814通过注料孔 815b将填充物注入到捻制的结交点 84a处, 同时,通过温控压线模 815上的加热体 815a对结交点 84a加热,使得灌注的填充物能够达 到粘溶状态, 以便填充物能够充满钢丝股内部的缝隙空间, 从而形成密封钢绳;
另一方面, 在制造密封钢绳期间, 捻制机 813可以将多根钢丝股 84围绕通讯线缆捻 制, 以便制造能够传输电信号的抽油绳。
然后, 将制得的密封钢绳通过去应力器 816进行去应力处理, 以便去除密封钢绳内部 的加工应力, 得到的密封钢绳 83储存在收线机 819上。
捻制钢绳时采用的钢丝股 84通过多根钢丝 87捻制而成, 并且在捻制的结交点灌料和 加热, 使得灌注的填充物 86充满钢丝的内部缝隙空间, 从而使得钢丝股也形成一个密封 的整体。
本发明中采用的填充物 86为高分子或橡胶及具有同类性质的材料。
2、 编织丝网
如图 9对本发明密封钢绳 83编织丝网的工艺流程图所示。
首先, 使步骤 1中制得的密封钢绳 83经过编织机 822, 编织机 822在密封钢绳 83的 外表面上编织丝网, 形成带有丝网的密封钢绳;
之后, 使带有丝网的密封钢绳通过可控加温箱 823, 可控加温箱 823对编织有丝网的 密封钢绳加热, 以便密封钢绳上的填充物软化;
最后, 使上述步骤制得的密封钢绳通过滚轮式紧网器 824进行缩径处理, 以便丝网将 密封钢绳包裹紧实, 并且避免了内部充填的填充物造成的钢绳直径突变。 制得的带有丝网 的密封钢绳 826储存在收线机 827上。
编织的丝网网目为菱形状, 长轴对角尺寸在 7-9mm之间, 编织丝网的钢丝直径在 0.6mm-1.4mm范围内, 编网层数为 1-3层。 为获得良好的柔韧性和绳体包裹的紧实性, 丝 网的网丝股采用多根钢丝捻制而成, 编网时根据钢绳主提重力及提捞频次的不同, 采用网 丝股的根数也不相同, 在 8根 -24根之间选择。
3、 涂覆外护密封层
本发明中的外护密封层可以采用高分子或者橡胶材料制造。
采用高分子材料制造钢绳的外护密封层时, 其工艺流程图如图 10a所示。
首先, 将步骤 2制得的带有丝网的密封钢绳 826进行预热处理(图中未示出), 使得 密封钢绳上的填充物达到粘溶状态, 预热温度根据填充物的粘结性而定;
然后, 使预热后的钢绳经过挤出机 832, 挤出机 832将塑化好的外护涂料涂覆在丝网 的外表面上, 使得外护涂料与钢绳上的填充物融为一体;
之后, 将上步得到的钢绳通过冷水槽 833冷却, 使得外护涂料和填充物冷却, 形成外 护密封层, 这样便得到了涂有外护密封层的钢绳 835, 储存在收线机 836上。
采用橡胶材料制造钢绳的外护密封层时, 其工艺流程图如图 10b所示, 预热后的钢绳 经过挤出机 832, 挤出机 832将塑化好的外护涂料涂覆在丝网的外表面上后, 将钢绳整体 经过硫化线 837进行硫化处理, 其它工艺过程与采用高分子材料制造外护密封层的工艺过 程相同。
4、 压光定径处理
本发明制造方法中的压光定径处理工艺流程如图 11所示。
首先, 将步骤 3中制得的涂有外护密封层的钢绳 835经过加热箱 842进行加热处理, 使得外护密封层达到塑化状态光亮;
然后, 钢绳整体经过温控定径模 843进行压光定径, 之后再经过冷水槽 844冷却, 使 得柔性抽油绳外表面光滑, 直径统一, 达到其使用标准, 这样便得到了本发明方法制造的 柔性抽油绳 23, 其结构图如图 12所示。
实施例 2
1、 通信导线的制备
将多股 线导体外涂覆一层抗高温外护绝缘层, 以制成通信导线。 其中, 通信导线要 求电阻率低、 外护层抗高温, 抗拉伸强度大, 在拉伸过程中具有良好的抗断裂即绝缘性, 具有可靠的工作稳定性。
2、 密封钢绳的制造
如图 8a所示, 将步骤 1制得的通信导线 89捻制成通信线缆股 85, 将通信线缆股 85 通过捻制机 813, 使得通信线缆股 85与多股钢丝股 84—起捻制, 其余工艺过程与实施例 1相同, 以制备密封钢绳 83a, 并使得通信线缆股 85位于密封钢绳 83a的芯部。
后续工艺过程与实施例 1相同, 这样, 便可得到本发明方法制造的具有通信功能的柔 性抽油绳 23a, 其结构图如图 12a所示。
尽管上文对本发明作了详细说明, 但本发明不限于此, 本技术领域的技术人员可以根 据本发明的原理进行修改, 因此, 凡按照本发明的原理进行的各种修改都应当理解为落入 本发明的保护范围。

Claims

权利要求书
1、 一种卷扬式提拉采油系统, 包括:
驱动总成(1 ), 具有卷筒(11 ) 以及驱动卷筒(11 )转动的驱动装置 (12);
机架 (2), 安装在地面上, 其上安装有滑轮(21 );
采油装置 (4), 位于井下油井管柱(5 ) 内;
抽油绳(23),一端缠绕在卷筒(11 )上,另一端绕过滑轮(21 )连接所述采油装置(4); 控制装置(9), 用于通过控制驱动装置(12)旋转, 驱动卷筒(11 )正反转, 从而通过 抽油绳 (23 ) 带动采油装置 (4)进行反复提拉采油操作;
其中, 所述采油装置 (4) 设有井下液柱高度检测器(6), 用于在检测到井下采集的液 体到达设定液柱高度时, 使所述控制装置 (9)控制所述采油装置 (4)进行提拉操作。
2、 如权利要求 1所述的卷扬式提拉采油系统, 其特征在于, 所述井下液柱高度检测器 ( 6 )通过有线或无线传输方式, 将检测到的设定液柱高度信号传输给所述控制装置, 以 便控制装置在收到设定液柱高度信号时, 控制驱动装置 (12)驱动卷筒(11 )转动, 再由 卷筒(11 )驱动抽油绳 (23 ) 带动采油装置 (4)把油井管柱(5 ) 内设定的液柱高度的液 体提拉到油井外。
3、 如权利要求 1或 2所述的卷扬式提拉采油系统, 其特征在于, 所述采油装置 (4) 还设有用于提拉油井管柱(5 ) 中液体的能够扩张的抽子(7), 所述抽子(7) 中装有一个 或多个其直径小于油井管柱内径的硬质高分子材料胶筒, 所述采油装置在油井管柱内壁滑 行(4)上行速度为 0.2m/S~1.2m/s时, 在上行的提拉力和油井管柱中液体重力的挤压下, 所述胶筒直径扩张为等于油井管柱内径。
4、 如权利要求 3所述的卷扬式提拉采油系统, 其特征在于, 所述油井管柱(5 ) 油井 管柱采用多根油管连接而成, 并使得油管间连接缝隙小得足以使所述高分子材料胶筒在油 管内平稳滑行, 避免因缝隙过大而造成破损。
5、 如权利要求 2所述的卷扬式提拉采油系统, 其特征在于, 所述井下液柱高度检测器 ( 6 )连接在所述抽油绳 (23 ) 的所述另一端, 包括: 用于检测井下采集的液体高度对应 的压力的压力变送器(62), 具有测压孔(62a), 压力变送器(62)安置在由压力变送器外 壳(62b)和连接在压力变送器外壳(62b)上的密封钢体(63 )形成的空间内; 所述密封 钢体(63 )上开有连接外界液体和测压孔(62a) 的传压孔(63a), 以便将与油井管柱中液 体高度对应的压力传递给压力变送器(62)。
6、 如权利要求 5所述的卷扬式提拉采油系统, 其特征在于,
所述密封钢体(63 ) 具有与外界油井管柱接触的导电接触部件;
所述压力变送器(62 )—方面与所述抽油绳 (23 ) 的金属芯电连接, 另一方面与所述 压力变送器外壳(62b) 电连接, 以便将检测到的井下液柱的信号通过抽油绳 (23 ) 和油 井管柱(5 )传递给所述控制装置。
7、 如权利要求 6所述的卷扬式提拉采油系统, 其特征在于, 所述导电接触部件包括安 置在密封钢体(63 ) 内的多对钢球(63b), 多对钢球中的每一对沿径向放置, 并且两钢球
( 63b) 由弹簧(63c)连接, 使得两钢球(63b)在弹簧(63c)作用下沿径向外突出, 以 便钢球(63b)接触所述油井管柱(5 ) 的内壁。
8、 如权利要求 2所述的卷扬式提拉采油系统, 其特征在于, 所述抽油绳 (23 )具有两 根通讯线缆, 所述压力变送器(62)分别与两根通讯线缆电连接, 以便将检测到的井下液 柱的信号通过抽油绳 (23 ) 的通讯线缆传递给所述控制装置。
9、 如权利要求 4所述的卷扬式提拉采油系统, 其特征在于, 所述压力变送器(62)具 有无线发射单元(62c), 压力变送器(62)将检测到的井下液柱的信号通过无线发射单元
( 62c)传递给所述控制装置。
10、 如权利要求 3所述的卷扬式提拉采油系统, 其特征在于, 所述油井管柱(5 ) 由多 节油管(5a、 5b)通过接箍(51 )连接而成, 在相邻油管(5a、 5b)之间设置尼龙环(53), 或钢环(53' )或位于接箍(51 ) 内壁上的凸起 (52), 以便减小相邻油管 (5a、 5b )之间 的连接缝隙。
11、如权利要求 1-10任一项所述的卷扬式提拉采油系统,其特征在于,所述抽油绳(23 ) 按如下方式形成:
采用捻制设备将多根钢丝股捻制成密封钢绳;
在密封钢绳外表面编织捆绑钢绳的丝网;
在丝网外表面上涂覆外护密封层, 将丝网及密封钢绳封闭在其内。
12、 如权利要求 11所述的卷扬式提拉采油系统, 其特征在于, 所述捻制密封钢绳按如 下方式形成:
(al )将多根钢丝股捻制成钢绳, 同时, 采用灌料机在钢丝股捻制的结交点灌料, 使得 灌注的填充物充满钢丝股内部缝隙空间, 形成密封钢绳;
(a2)将密封钢绳进行去应力处理, 以便去除密封钢绳的内部加工应力。
13、 如权利要求 12所述的卷扬式提拉采油系统, 其特征在于, 在所述结交点灌料的同 时对结交点进行加热, 使得灌注的填充物达到粘溶状态, 以便充满钢丝股内部缝隙空间。
14、 如权利要求 11所述的卷扬式提拉采油系统, 其特征在于, 所述编织丝网按如下方 式形成:
( b 1 )采用编织机在所述密封钢绳的外表面上编织丝网;
(b2)采用可控加温箱对编织有丝网的密封钢绳加热, 使得密封钢绳上的填充物软化; (b3 )将带有丝网的密封钢绳进行缩径处理, 使得丝网将所述密封钢绳包裹紧实。
15、 如权利要求 14所述的卷扬式提拉采油系统, 其特征在于, 所述钢丝股和所述丝网 的网丝股分别采用多根钢丝捻制而成, 在钢丝捻制的结交点处灌料, 使得灌注的填充物充 满钢丝内部缝隙空间。
16、 如权利要求 15所述的卷扬式提拉采油系统, 其特征在于, 所述涂覆外护密封层按 如下方式形成:
(cl )对裹有丝网的密封钢绳进行预热处理, 使得密封钢绳上的填充物达到粘溶状态; (c2)将塑化好的外护涂料涂覆在外表面上,使得外护涂料与所述填充物融为一体,形 成外护密封层。
17、 如权利要求 16所述的卷扬式提拉采油系统, 其特征在于, 还包括对所述涂覆有外 护密封层的钢绳依次进行如下处理:
(dl )将所述涂覆有外护密封层的钢绳进行加热, 使得外护密封层达到塑化状态; (d2 )钢绳整体通过定径模进行压光定径处理, 使所述钢绳整体外表面光滑, 直径统
18、 如权利要求 16所述的卷扬式提拉采油系统, 其特征在于, 在制造密封钢绳时, 多 根钢丝股围绕通讯线缆捻制。
19、 一种如权利要求 1-10任一项所述的卷扬式提拉采油系统的抽油绳的制造方法, 包 括以下步骤:
采用捻制设备将多根钢丝股捻制成密封钢绳;
在密封钢绳外表面编织捆绑钢绳的丝网;
在丝网外表面上涂覆外护密封层, 将丝网及密封钢绳封闭在其内。
20、 如权利要求 19所述的方法, 其特征在于, 所述捻制密封钢绳按如下方式制造: (al )将多根钢丝股捻制成钢绳, 同时, 采用灌料机在钢丝股捻制的结交点灌料, 使得 灌注的填充物充满钢丝股内部缝隙空间, 形成密封钢绳;
(a2)将密封钢绳进行去应力处理, 以便去除密封钢绳的内部加工应力。
21、 如权利要求 20所述的方法, 其特征在于, 在所述结交点灌料的同时对结交点进行 加热, 使得灌注的填充物达到粘溶状态, 以便充满钢丝股内部缝隙空间。
22、 如权利要求 19所述的方法, 其特征在于, 所述编织丝网按如下步骤制造: ( b 1 )采用编织机在所述密封钢绳的外表面上编织丝网;
(b2)采用可控加温箱对编织有丝网的密封钢绳加热, 使得密封钢绳上的填充物软化; (b3 )将带有丝网的密封钢绳进行缩径处理, 使得丝网将所述密封钢绳包裹紧实。
23、 如权利要求 22所述的方法, 其特征在于, 所述钢丝股和所述丝网的网丝股分别采 用多根钢丝捻制而成, 在钢丝捻制的结交点处灌料, 使得灌注的填充物充满钢丝内部缝隙 空间。
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Cited By (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103808228A (zh) * 2014-02-27 2014-05-21 中国石油大港油田勘探开发研究院 抽油机冲次调整检测装置
CN104033134A (zh) * 2013-12-19 2014-09-10 鄂德刚 一种低矮型超长冲程智能控制卷扬式提拉采油系统及工作方法
CN104728098A (zh) * 2013-12-19 2015-06-24 鄂德刚 一种多级柱塞超长冲程抽油泵
CN105041629A (zh) * 2015-07-17 2015-11-11 盐城市佳鑫石化机械制造有限公司 新型防偏磨液力采油装置
CN106761571A (zh) * 2016-11-26 2017-05-31 东北石油大学 密封钢丝绳数控卷扬抽油机
CN106837253A (zh) * 2017-02-23 2017-06-13 江苏恒瑞石油装备机械制造有限公司 双驱抽油机构
CN106869868A (zh) * 2017-03-29 2017-06-20 毛国武 双臂摇线作井杆往复运动节能抽油机
CN109488246A (zh) * 2017-09-12 2019-03-19 中国石油天然气股份有限公司 抽油机防喷装置和抽油机
CN115874992A (zh) * 2022-11-11 2023-03-31 中国石油天然气集团有限公司 一种油气井缓冲式差速自锁抽汲工具及抽汲方法

Citations (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN2308704Y (zh) * 1997-08-14 1999-02-24 西安凯宏工业有限责任公司 车载抽油装置
CN2729304Y (zh) * 2002-12-11 2005-09-28 李青 一种使用柔性抽油杆的采油装置
CN201158773Y (zh) * 2008-02-25 2008-12-03 鄂德刚 一种注塑复合钢丝绳
CN201359871Y (zh) * 2009-02-21 2009-12-09 大庆北研石油设备制造有限公司 一种可加热和传送数据的注塑复合钢丝绳
CN101876240A (zh) * 2010-06-28 2010-11-03 苏州大一装备科技有限公司 一种全自动采油设备
CN201778768U (zh) * 2010-07-19 2011-03-30 大庆惠博普石油机械设备制造有限公司 智能提捞抽油机
CN201835821U (zh) * 2010-10-08 2011-05-18 大庆北研石油设备制造有限公司 用于采油的井下液柱高度有线检测器
CN201835822U (zh) * 2010-10-08 2011-05-18 大庆北研石油设备制造有限公司 用于采油的井下液柱高度检测器
CN201835812U (zh) * 2010-10-08 2011-05-18 大庆北研石油设备制造有限公司 用于采油的井下液柱高度无线检测器
CN102234943A (zh) * 2010-05-06 2011-11-09 大庆北研石油设备制造有限公司 一种柔性抽油绳的制造方法
CN102444393A (zh) * 2010-10-08 2012-05-09 大庆北研石油设备制造有限公司 一种智能卷扬式提拉采油系统

Patent Citations (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN2308704Y (zh) * 1997-08-14 1999-02-24 西安凯宏工业有限责任公司 车载抽油装置
CN2729304Y (zh) * 2002-12-11 2005-09-28 李青 一种使用柔性抽油杆的采油装置
CN201158773Y (zh) * 2008-02-25 2008-12-03 鄂德刚 一种注塑复合钢丝绳
CN201359871Y (zh) * 2009-02-21 2009-12-09 大庆北研石油设备制造有限公司 一种可加热和传送数据的注塑复合钢丝绳
CN102234943A (zh) * 2010-05-06 2011-11-09 大庆北研石油设备制造有限公司 一种柔性抽油绳的制造方法
CN101876240A (zh) * 2010-06-28 2010-11-03 苏州大一装备科技有限公司 一种全自动采油设备
CN201778768U (zh) * 2010-07-19 2011-03-30 大庆惠博普石油机械设备制造有限公司 智能提捞抽油机
CN201835821U (zh) * 2010-10-08 2011-05-18 大庆北研石油设备制造有限公司 用于采油的井下液柱高度有线检测器
CN201835822U (zh) * 2010-10-08 2011-05-18 大庆北研石油设备制造有限公司 用于采油的井下液柱高度检测器
CN201835812U (zh) * 2010-10-08 2011-05-18 大庆北研石油设备制造有限公司 用于采油的井下液柱高度无线检测器
CN102444393A (zh) * 2010-10-08 2012-05-09 大庆北研石油设备制造有限公司 一种智能卷扬式提拉采油系统

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104033134A (zh) * 2013-12-19 2014-09-10 鄂德刚 一种低矮型超长冲程智能控制卷扬式提拉采油系统及工作方法
CN104728098A (zh) * 2013-12-19 2015-06-24 鄂德刚 一种多级柱塞超长冲程抽油泵
CN103808228A (zh) * 2014-02-27 2014-05-21 中国石油大港油田勘探开发研究院 抽油机冲次调整检测装置
CN105041629A (zh) * 2015-07-17 2015-11-11 盐城市佳鑫石化机械制造有限公司 新型防偏磨液力采油装置
CN106761571A (zh) * 2016-11-26 2017-05-31 东北石油大学 密封钢丝绳数控卷扬抽油机
CN106837253A (zh) * 2017-02-23 2017-06-13 江苏恒瑞石油装备机械制造有限公司 双驱抽油机构
CN106869868A (zh) * 2017-03-29 2017-06-20 毛国武 双臂摇线作井杆往复运动节能抽油机
CN109488246A (zh) * 2017-09-12 2019-03-19 中国石油天然气股份有限公司 抽油机防喷装置和抽油机
CN109488246B (zh) * 2017-09-12 2023-09-26 中国石油天然气股份有限公司 抽油机防喷装置和抽油机
CN115874992A (zh) * 2022-11-11 2023-03-31 中国石油天然气集团有限公司 一种油气井缓冲式差速自锁抽汲工具及抽汲方法

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