WO2001055552A1 - An oil pumping unit with a counterweight whose centroid can be adjusted - Google Patents
An oil pumping unit with a counterweight whose centroid can be adjusted Download PDFInfo
- Publication number
- WO2001055552A1 WO2001055552A1 PCT/CN2001/000005 CN0100005W WO0155552A1 WO 2001055552 A1 WO2001055552 A1 WO 2001055552A1 CN 0100005 W CN0100005 W CN 0100005W WO 0155552 A1 WO0155552 A1 WO 0155552A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- balance
- center
- hanging
- hook
- pumping unit
- Prior art date
Links
- 238000005086 pumping Methods 0.000 title claims abstract description 66
- 239000003638 chemical reducing agent Substances 0.000 claims abstract description 6
- 238000005452 bending Methods 0.000 claims description 25
- 239000000725 suspension Substances 0.000 claims description 11
- 230000009471 action Effects 0.000 claims description 9
- 241000283074 Equus asinus Species 0.000 claims description 8
- 229910000831 Steel Inorganic materials 0.000 claims description 2
- 239000010959 steel Substances 0.000 claims description 2
- 238000005259 measurement Methods 0.000 claims 1
- 230000005540 biological transmission Effects 0.000 abstract description 3
- 230000007246 mechanism Effects 0.000 abstract description 2
- 238000010586 diagram Methods 0.000 description 12
- 238000000034 method Methods 0.000 description 10
- 230000005484 gravity Effects 0.000 description 7
- 230000033001 locomotion Effects 0.000 description 6
- 239000013598 vector Substances 0.000 description 6
- 230000000694 effects Effects 0.000 description 5
- 238000009434 installation Methods 0.000 description 5
- 238000012546 transfer Methods 0.000 description 5
- 238000013461 design Methods 0.000 description 3
- 210000005069 ears Anatomy 0.000 description 3
- 238000005381 potential energy Methods 0.000 description 3
- 125000006850 spacer group Chemical group 0.000 description 3
- 238000003466 welding Methods 0.000 description 3
- 238000013475 authorization Methods 0.000 description 2
- 230000008901 benefit Effects 0.000 description 2
- 230000008859 change Effects 0.000 description 2
- 239000002131 composite material Substances 0.000 description 2
- 238000006073 displacement reaction Methods 0.000 description 2
- 238000012423 maintenance Methods 0.000 description 2
- 238000004519 manufacturing process Methods 0.000 description 2
- 230000007935 neutral effect Effects 0.000 description 2
- 238000005192 partition Methods 0.000 description 2
- 238000012360 testing method Methods 0.000 description 2
- 230000001133 acceleration Effects 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000033228 biological regulation Effects 0.000 description 1
- 230000003247 decreasing effect Effects 0.000 description 1
- 238000004146 energy storage Methods 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 238000011010 flushing procedure Methods 0.000 description 1
- NJPPVKZQTLUDBO-UHFFFAOYSA-N novaluron Chemical compound C1=C(Cl)C(OC(F)(F)C(OC(F)(F)F)F)=CC=C1NC(=O)NC(=O)C1=C(F)C=CC=C1F NJPPVKZQTLUDBO-UHFFFAOYSA-N 0.000 description 1
- 238000002360 preparation method Methods 0.000 description 1
- 230000002035 prolonged effect Effects 0.000 description 1
- 230000009467 reduction Effects 0.000 description 1
- 230000003014 reinforcing effect Effects 0.000 description 1
- 238000005096 rolling process Methods 0.000 description 1
- 238000007665 sagging Methods 0.000 description 1
- 238000003860 storage Methods 0.000 description 1
Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B47/00—Pumps or pumping installations specially adapted for raising fluids from great depths, e.g. well pumps
- F04B47/02—Pumps or pumping installations specially adapted for raising fluids from great depths, e.g. well pumps the driving mechanisms being situated at ground level
-
- E—FIXED CONSTRUCTIONS
- E21—EARTH OR ROCK DRILLING; MINING
- E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B43/00—Methods or apparatus for obtaining oil, gas, water, soluble or meltable materials or a slurry of minerals from wells
- E21B43/12—Methods or apparatus for controlling the flow of the obtained fluid to or in wells
- E21B43/121—Lifting well fluids
- E21B43/126—Adaptations of down-hole pump systems powered by drives outside the borehole, e.g. by a rotary or oscillating drive
- E21B43/127—Adaptations of walking-beam pump systems
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B47/00—Pumps or pumping installations specially adapted for raising fluids from great depths, e.g. well pumps
- F04B47/14—Counterbalancing
Definitions
- the invention relates to a lower balanced beam pumping unit used in an oil field.
- High-efficiency energy-saving rod pumping unit that has obtained national invention patents (patent number: 92115106. 3, authorization date: 99. 2. 10), and a balanced-arm two-stage balanced beam pumping unit that has obtained national utility model patents ( Patent number: 96201421. 4, Authorization announcement date: 98. 8. 26), all belong to the lower balance beam pumping unit.
- Their disadvantages are: the lower distance H of the lower balance mass cannot be adjusted according to the actual requirements, and the size of H cannot be measured during the on-site adjustment. Therefore, H cannot be specified as the value that actually needs to be specified, and it cannot reach the maximum value.
- An object of the present invention is to provide a lower balanced beam pumping unit that can set the center of mass down distance H at an optimal position according to the actual requirements of the well conditions and pumping unit operating conditions.
- a type of under-centered balanced beam pumping unit including power machine 1: belt drive 3; reducer 4; crank 5; connecting rod 6; cross beam and cross beam bearing block 10; integrated or combined Curved beam '8; beam support 7; sheet or wheel donkey head 9 and rope hanger 11 hanging on the donkey head; brake device 12; bracket 14; chassis 2 and impact bearing device 13 mounted on the chassis
- a lower balance beam device connected at the tail end of the curved beam which can also have a conventional balance, which is characterized in that: the lower balance beam device is a hinged hanging beam end with a specified center of mass structure Lower balance box / block.
- the centroid of the lower beam balance box / block can be specified at the best when the pumping unit is installed or before the installation, based on the calculated data according to the working conditions and well conditions. Position, that is, H will decay to the specified optimal value to obtain the best balance effect.
- the pumping unit of the present invention has both simple structure and convenient assembly and disassembly. The energy saving effect has significant advantages, specifically: simple and reliable structure, low cost and convenient maintenance and disassembly are better than conventional beam pumping units: the performance is better than the existing lower balanced beam pumping units.
- FIG. 1 is a schematic structural diagram of the first embodiment.
- FIG. 2 is a schematic structural diagram of the second embodiment.
- FIG. 3 is a schematic structural diagram of the third embodiment.
- FIG. 4 is a schematic structural diagram of a fourth embodiment.
- Figure 5 shows one of the solutions of the active mass centering block.
- Figure 6 is the second scheme of the active mass centering block.
- Figure 8 is the fourth scheme of the active mass centering block.
- Figure 9 is the fifth scheme of the active mass centering block.
- Figure 10 is the sixth scheme of the active mass centering block.
- Fig. 11 is the seventh scheme of the active mass centering block.
- Figure 12 shows the eighth solution of the center-of-mass positioning block.
- FIG. 13 is a schematic structural diagram of the fifth embodiment.
- Fig. 14 shows one embodiment of the telescopic shaft.
- Figure 15 is the second embodiment of the telescopic shaft.
- FIG. 16 is a schematic structural diagram of a sixth embodiment.
- Fig. 17 is a schematic diagram of an angle adjusting device.
- Figure 18 is one of the structural schemes of the frame type balance box.
- Figure 19 is the second structural scheme of the frame type balance box.
- Figure 20 is the third structural solution of the frame type balance box.
- Figure 21 is the fourth structural scheme of the frame type balance box.
- Figure 22 is a schematic diagram of a triangular crank.
- Figure 23 shows the balance of the pendulum.
- Figure 24 is a simplified diagram of the movement of the lower balanced beam pumping unit.
- Figure 25 is a simplified diagram of the beam composite pumping unit.
- Fig. 26 is a comparison chart of the crank torque of the type test of the machine and the conventional machine.
- Figure 27 compares the crank torque of the pumping operation between this machine and the conventional machine.
- Embodiment 1 is one of the basic modes for specifying a balanced beam pumping unit under the center of mass. Its basic structure is the same as that of the existing lower balance beam pumping unit: After the power machine 1 is decelerated by the belt transmission 3 and the reducer 4, the cranks 5 installed at both ends of the reducer output shaft are driven to rotate, and then the connecting rod 6 and Crossbeam and crossbeam bearing block 10, which drives the curved beam 8 to swing up and down around the center 0 of the beam. The donkey head mounted on the front end of the curved beam synchronously swings, and the rope hanger hanging on the donkey head is connected with the sucker rod. The up and down movement completes the pumping work.
- a lower beam balancing device with a predetermined center of mass structure is a lower beam balancing with a predetermined center of mass hanging on the tail end of a curved beam
- the box specifies that the centroid structure includes two parts: one is to modulate the centroid structure, and the other is to determine the centroid structure.
- Modified center-of-mass structure adopts a frame structure floor balance box.
- One frame is welded with three to four uprights 17 to form a frame.
- the frame connects the upper balance box 16 and the lower balance box 15 to have two symmetrical planes.
- one symmetry plane coincides with the whole machine symmetry plane, and the other symmetry plane FF is perpendicular to the beam action line 00; and the upper balance box 16 and the lower balance box 15 are each provided with at least one horizontal shelf 18 on the upper side, and the upper
- the side or bottom of the balance box 16 and the lower balance box 15 are provided with a simple structure of a weight-removing door, for example, opening a hole; the opening and closing of the hole is controlled by a plug board.
- Increasing or decreasing the number of weights in the upper balance box 16 and the lower balance box 15 can make the center of mass G move along FF to achieve the purpose of adjusting the distance H under the center of mass.
- the heavy-duty door is used to unbalance the mass.
- the partition 18 is used to prevent the weight in the balance box from rolling during the operation of the pumping unit.
- the measurement center of mass structure is the hanging shaft of the floor balance box.
- the hanging shaft and the scale structure are:
- the front and rear sides of the floor balance box are provided with hanging shafts 19 and 22.
- a groove for suspending the wire rope is made.
- the front and rear hanging shafts are staggered by a distance in the height direction of the floor balance box.
- the floor balance box is hinged / hanged on the hanging end of the bending beam 23 through the hanging shaft. Or hook on 23.1.
- a scale 27 is set from the beam action line.
- the containment structure is that the distance between the two vertical columns 17 on the front side of the building balance box in the vertical direction of the plane of symmetry of the whole machine is greater than the width of the tail end of the bending beam, so that when measuring the center of mass of the balancing device, the tail end of the bending beam can extend into the column. Neutral; At the same time, a bolt 24 is provided between the column 17 and the tail end of the bending beam.
- the floor balance box is fixed to the tail end of the bending beam by the bolt when the pumping unit is in operation. When the balance is adjusted, the bolt is removed or exited.
- the floor balance box is in a free dumpling hanging state.
- this embodiment adopts a wedge lifting structure: the inside of the balance box is fixed with a pair of straight slot seats 26 which are opened upward, and the straight slot is provided with the latch 24, and the bottom bolt 26 of the straight slot seat is rotated. 1 Or drive a wedge between the latch 24 and the bottom surface of the straight slot seat, and squeeze the latch 24 upward into the wedge slot of the wedge slot seat 25.
- the wedge slot seat 25 is integrated with the tail end of the bending beam and opens downward.
- the lower half of the cross section of the latch 24 is rectangular, and the upper half is wedge-shaped.
- the bolt 24 is placed in the groove of the straight groove seat 26, and it is firmly connected with the tail end of the bending beam by bolts.
- a hook head structure can also be used.
- the tail end of the bending beam has a hook head that opens upward.
- a hook bolt 24 is placed in the hook head.
- the front side of the balance box of the pumping unit works against the bolt when the pumping unit is working.
- Bolts can also be used Connect them together. When the hanging shaft 19 or 22 is lifted, the heavy vertical lines KK and JJ must pass through the center of mass G of the balancing device; the floor balance box is symmetrical about FF, and G is on FF, so KK; JJ; FF must meet G.
- G There are two methods for determining G: one is to lift the floor balance box in the center of the hanging shaft 19 or 22, and the intersection point of the vertical line KK or JJ with the center of the hanging shaft and FF is the center of mass G; the other is The floor balance box is hinged on the hanging seat 23 or U-shaped hook 23.1 at the tail end of the bending beam through the hanging shaft 19 or 22, and the bolt 24 is removed or withdrawn, and the tail end of the bending beam extends into the column 17 In neutral, the floor balance box is in a free hanging state, and the intersection of the corresponding heavy vertical line and FF is the center of mass G.
- the distance H below the center of mass of the building balance box can be read, and at the same time, it can be adjusted to meet the requirements by adjusting the position of the center of mass.
- the former method is used for preparation before installation; the latter method is used for fine adjustment or replacement of strokes and balance during stroke, without crane.
- a curved bending beam is used as a whole, and a combined curved beam formed by connecting a balance arm 8.1 to the bending beam may also be used.
- the multi-hanging balance box is:
- the balance box 15 is made of an independent overall rectangular structure, and its front; at least three hanging shafts are arranged at different distances on the rear sides, and these hanging shafts are connected to the front and back sides of the balance box through lifting eyes 20; 21 1 , Or directly through the holes on the left and right sides of the balance box, the balance box is hinged on one of these hanging shafts on the pedestal 23 or U-shaped hook 23.1 linked to the end of the bending beam.
- the lower distance H of G can be read from the scale 27; the hanging shaft can be adjusted to change the center of mass G
- the lower distance H, H will increase or decrease according to the misalignment between the hanging shafts.
- Bracket structure Another feature of this embodiment is the use of a tower double-layer bracket structure: the entire bracket is formed by bolting the upper bracket 14 and the lower bracket 55, and the lower bracket 55 can be welded to the chassis as a whole or can be bolted together;
- the bracket 14 is designed as an integral steel structure or an assembled triangular brace similar to the existing structure and is bolted to the lower bracket.
- the advantage of this bracket structure is that the whole machine has good rigidity and is easy to transport. Both the present invention and the conventional beam pumping unit widely used now can adopt such a bracket structure.
- the first embodiment may also adopt the multi-hanging shaft / hook structure and the tower double-layer support structure described herein.
- Embodiment 3 Referring to FIG. 3, it is different from the second embodiment in that: the upper part of the balance box 15 uses two columns 17, an upper welding cross bar 17.1, and a side welding reinforcing plate 17.2, extending a hanging back; four columns can also be used A top plate is added on top, and a frame structure is extended on the upper part of the balance box; at least three hanging shafts 22 are arranged on the posts constituting the hanging back or the frame structure, and these hanging shafts pass through the holes of the column 17 or are welded or bolted to the columns 17 can also be mounted on the front side of the column through the lifting ears.
- the hanging shaft can also be installed at the tail end of the curved beam, and the post constituting the hanging back or the frame structure is provided with a hook.
- Embodiment 4 is the second basic mode of specifying a center-center underbalanced beam pumping unit, which is different from the foregoing embodiment in that a free hinge structure is adopted at the lower end of the balance box / block and the end of the beam.
- a free hinge structure is adopted at the lower end of the balance box / block and the end of the beam.
- the center of mass structure adopts an adjustment block, balance box / block hinge system, an adjustment block 30 directly or through a connecting plate 30. 1 is connected to the tail end of the curved beam 8 or integrated with it, the balance box / block 29
- Two symmetrical suspenders or suspenders 31 are extended upward. At the position shown in the figure, the alignment block 30 and the symmetric line of the suspender 31 coincide.
- the aligner 30 and the suspender 31 are made with Equal number of holes with equal spacing.
- the hanging / hinging shaft 28 penetrates into a certain hole in the hole system, and the balance box / block 29 is freely hinged at this hole position with the adjustment block 30.
- the center G of the hole position is the hinge point; because the entire weight of the balance box / block Must act on the beam through the hinge point G, the actual center of mass will not work, its balance effect and the entire weight of the balance box / block are all set
- the hinge point G is the same at middle, so the hinge point G is called the active center of mass of the lower balance device, and L and H are the rear and lower distances of G, respectively.
- the hanging / hinging shaft 28 is worn in different holes, and the same balance box / block has different H; it is also possible to make multiple rows of hole systems on the adjustment block 30, and adjust H and L at the same time. If there are two hanging / hinging shafts 28, put on the hanging / hinging shaft according to the specified center of mass position, and then remove the previous hanging / hinging shaft, the adjustment work will be very convenient.
- Figure 5 is a hook-shaped U-shaped groove hinge structure: the right side of the adjustment block 30 is connected with the connecting plate 30. 1 with the end of the bending beam firmly or bolted, the left side is made At least three hook-shaped U-shaped grooves 52, the balance box is hinged in the hook-shaped U-shaped groove: The left and right sides of the balance box 29 extend upward from the hanging plate 31, and the two hanging plates are provided with concentric circular holes at the top, and the holes are provided with In the bearing, the hanging / hinging shaft 28 is penetrated in the bearing and fixed relatively axially, and the middle shaft section is placed in the hook-shaped U-shaped groove. The center of the bottom half circle of the hook-shaped U-shaped groove is the center of mass for balancing the mass. Because there are at least three hook-shaped U-shaped grooves, there are at least three lower distances H to choose from to suit the balance of the three strokes of the pumping unit. Claim.
- the hook-shaped U-shaped groove can also be changed to a hook that is hinged to the end of the curved beam or the positioning plate.
- the inside of the hook can be U-shaped or rectangular.
- the hook and the positioning block or swim The hinge point at the end of the beam is the acting center of mass.
- This structure can be called a hook-balance box / block hinge system.
- FIG. 6 is a labyrinth U-shaped groove hinge structure: It is different from FIG. 5 in that the positioning block 30 is provided with multiple rows of lateral channels, and each row of channels hangs multiple U-shaped grooves, which is called a labyrinth U-shape
- the slot 53 and the entrance of each channel are sealed with a multi-tooth unloading cover plate 30.2, and the multi-tooth unloading cover plate is bolted to the positioning block.
- the positioning block adopts this scheme, and both the rear distance L and the lower distance H acting on the center of mass G are adjustable.
- Figure 7 is a rectangular slot hinge structure: 'The positioning block 30 is provided with at least three rectangular slots 36, and the hanging / hinging shaft 28 is hung / hinged in the rectangular slot through the suspension rod 31 and the adjusting block 30. There are two ways of hanging / hinging. (1) The middle section of the hanging / hinging shaft 28 is hinged with a rectangular bearing housing 32, which is placed in the rectangular groove of the adjusting block, and the upper end of the boom 31 is a looper. At both ends of the hanging / hinging shaft 28, the lower ends are connected to the shaft head loopers connected to the left and right sides of the balance box / block 29, and are axially fixed.
- the upper end of the suspender 31 and the two ends of the hanging / hinging shaft 28 are hinged through bearings.
- the middle of the hanging / hinging shaft 28 is a rectangular shaft section 32, which is placed in a rectangular groove of the positioning block 30.
- the rectangular groove of the positioning block 30 is sealed with a toothed unloading cover 30.2.
- the center of the rectangular bearing block or the middle rectangular shaft section 32 integrated with the hanging / hinge shaft is the center of mass of the balancing device, and the distance from the beam action line 00 is its lower distance H.
- FIG. 8 is a hook-shaped rectangular slot hinge structure. The difference from FIG. 7 is that the rectangular slot on the positioning block 30 is changed to a hook-shaped rectangular slot 54.
- the positioning block adopts this scheme, and the loading and unloading operations will be as convenient as in Figure 5.
- FIG. 9 is a long-slot hinge structure, which is different from the rectangular-slot hinge structure of FIG. 7 in that: (1) the plurality of rectangular grooves on the positioning block are changed to rectangular long grooves 37 which are open or not open, The upper end of the open long slot is pulled with bolts 34 and nuts 35 to enhance the strength of the positioning block and to clamp the hanging / hinge shaft or rectangular outline bearing seat. (2) A rectangular bearing or a middle rectangular shaft section 32 integrated with the hanging / hinging shaft 28 is placed in the long groove, and a pad 33 of varying thickness is placed at the bottom of the long groove to adjust the position of the acting center of mass. Distance from the bottom?
- the spacer 33 may further include a spacer with a U-shaped groove for placing a circular hanging / hinge shaft in a rectangular groove.
- the intermediate member 31 is a suspension plate or a suspension rod.
- the long groove is at least one or two or three parallel grooves.
- Fig. 10 is a simple jack connected by a screw 42 and a nut 43. It can be used instead of the spacer at the bottom of the long groove in Fig. 9 to continuously adjust the lower distance H of the center of mass.
- FIG. 11 is also a long-slot hinge structure, except that the long slot 37 on the positioning block 30 is closed or opened downward, and the top of the positioning block is provided with "Screw" tired mother mechanism, the upper end of the screw 44 is provided with a square head for rotation, and the lower end is connected to the rectangular bearing seat or the rectangular shaft section 32 in the axial direction of the screw; the balance box is hung on both sides of the rectangular bearing seat 32 through the suspension rod 45 Extend or extend from the rectangular shaft section 32 to both sides of the hanging / hinge shaft 28.
- This positioning block scheme can continuously adjust the lower distance H of the center of mass G, but prevent the screw nut from rusting.
- FIG. 12 is a connection scheme between the positioning block 30 and the end of the bending beam: there is a connecting plate 30.1, which has rectangular or trapezoidal convex teeth 38, and the inside of the positioning block 30 has a corresponding rectangular or trapezoidal groove. 39 is engaged with it, and the upper part of the adjusting block 30 is fixedly connected with the connecting plate 30. 1 by bolts 34 and nuts 35, and the connecting plate is integrally connected with the tail end of the bending beam.
- the downward distance H of the acting center of mass can also be adjusted, and it can be used as the positioning scheme of the positioning block.
- the positioning block 30 can be block-shaped, plate-shaped, strip-shaped or hollow structure. It can be connected to the end of the bending beam-an independent body: it can also be integrated with the end of the bending beam. At this time, the adjustment block can be regarded as the end of the bending beam. Holes and grooves are holes and grooves made at the end of the curved beam.
- the suspension rod 31 may be plate-shaped, rod-shaped, strip-shaped, or meaning-shaped, or both ends may be meaning-shaped.
- Embodiment five Referring to FIG. 13, this is the third of the basic modes of specifying the center-of-center balanced beam pumping unit. It is specified that the center-of-center structure of the under-balanced device adopts a triangular truss * balance box / block hinge / hanging system with a telescopic rod 40; 41 It is articulated with the beam 8 and the lower ends are articulated with each other to form an adjustable triangular truss-type curved beam.
- the balance box / block 29 is freely hinged / hanged directly or at a hinge point G on the lower part of the triangle truss directly or through a hanging rod / hook. G is the working center of mass of the lower balancing device.
- 40 and 41 are telescopic rods with adjustable length, G can be adjusted to any specified position within the design range according to actual requirements.
- the articulation points of the telescopic rods 40; 41 and the beam 8 are not necessarily in the position shown in FIG. 13, but can also be hinged with the beam in other positions, and the hinge support can be bolted to the upper, lower or tail end of the beam, And with an alignment structure. If the balance block 29 is made into a circle or a rectangle, the center of mass of the balance block 29 can also coincide with the hinge center and can be hung on the hinge axis G.
- the fourth embodiment can also do the same.
- Figure 14 is one of the telescopic rod solutions: a sliding sleeve of a core tube 46 and a sleeve 47, the sleeve is provided with at least one circular hole, the core tube is made with a series of circular holes, and the screw 34 is inserted into the different holes of the sleeve and the core tube.
- Medium that is, the length of the telescopic shaft can be adjusted, and this length can be read from the scale 27 engraved on the heart tube.
- Figure 14 is the second solution of the telescopic rod: square or circular tubes 48, 49 with right-handed or left-handed nuts, and they are connected by a double-headed left-handed right-handed screw 50 to form another telescopic rod.
- the groove of the double-headed left-handed right-hand screw 50 is also engraved with a scale 27 indicating the length of the telescopic rod.
- Embodiment 6 is the fourth of the basic modes for specifying a balanced beam pumping unit under the center of mass, which is characterized by using a swing method to adjust the distance under the center of mass of the balancing device H:
- the curved beam uses a balance arm 8.1.
- the angle devices A and B are enlarged as shown in FIG. 17. It is composed of a mounting bracket 60 and an angle adjusting piece 61. The arc surface of the mounting frame and the angle adjusting piece 61 have the same diameter d, and both are centered on the hinge axis.
- the balance box structure of the present invention has various forms, including an overall layered structure, a frame structure, a back hanging structure, a free hinge structure, and the like.
- the overall layered structure 62 (Fig. 16) is a balance box made into a whole.
- the interior can also be designed with a bracket 56 or a wall frame 58, and a shelf 59. It can also be seated on the overall balance box, connected to the lower part, or connected to an auxiliary, Under the box 57.
- the basic structure of the frame is shown in Figs. 18-21. Three or four equal-length posts 63 are used to connect the top plate 65 and the bottom plate 64 to form a frame 66.
- the upper part of the frame is connected to the upper box 16 ( Figure 19) or the lower box 15 ( Figure 19). 20), or an upper case and a lower case are connected at the same time (Figure 18), and the lower case can be connected to the lower case.
- the connection may be a commonly used bolt connection or a joint welding.
- the frame can also be equipped with a conventional auxiliary balance box 68 (Figure 21) by conventional means, and a conventional lifting or lifting device can be used to adjust the auxiliary balance. The position of the box is then fixed.
- the back-hanging structure ( Figure 3) is a variant of the frame structure, which is used when there is no need to set up a box.
- the free-hinged structure is shown in Figures 4-13. The production requirements are high. From the end of the donkey's head, the balance box / block must be symmetrical to the left and right.
- the lower part of the balance box / block can also be connected with multiple auxiliary lower boxes / blocks, and the top surface of the lowermost balance box / block is provided with a gasket 67 with a thickness of not less than 5-10 mm.
- the lower case is unloaded on the flushing device, and the gasket is removed.
- the pumping unit can operate normally without colliding with the top of the removed box.
- the removed gasket can be reset and the auxiliary lower case can be reattached to the balancing device. .
- This structure will help reduce the load on the motor during the initial installation and will be beneficial to operations such as "touching the pump”.
- the bracket of the pumping unit of the present invention may adopt a tower double-layer bracket structure or a conventional structure.
- the crank of the pumping unit of the present invention may adopt a straight crank or a triangular crank.
- FIG. 22 is a schematic structural diagram of a triangular crank, which is characterized in that a straight line connecting the centers of the crank pin holes and the center of the crank spindle hole is connected into a triangle.
- the embodiments of the centrifugal beam pumping unit under the center of gravity are all of the front structure, and the rear structure can also be adopted. As long as the hinge point of the connecting rod 6 and the beam 8 is set at the rear of the curved beam, the rear can be obtained.
- the center-mounted balanced beam pumping unit is installed under the specified center of mass.
- the present invention provides that the center-of-mass balance device can be used alone or mixed with the conventional balance method. Therefore, the present invention can also be used for energy-saving reconstruction of existing conventional beam pumping units, as long as it is a beam pumping unit, Both can be used in accordance with the provisions of the invention under the center of mass balance device.
- the pumping unit of the present invention is in a leading position in all aspects: 1.
- the peak torque of the crankshaft is reduced by 30 to 60%; the power saving rate is 30 to 50%.
- the structure of the whole machine is simple and reliable. 3. Easy installation and maintenance. 4, easy to adjust the balance, the balance rate can reach 98%. 5.
- the whole machine is light in weight, with a reduction of 30%. 6, Reduce manufacturing costs by 20%. 7.
- the mechanical condition of the machine is improved, the wearing parts are reduced, and the machine life is prolonged.
- the inertia moment of the pumping unit will be generated by Q, mc of the beam system and the mass m (force arm L) of the beam and the moment of inertia J of the beam. Their moments to the swing center 0 of the beam are:
- Mn (Li 2 Q + L 2 m + H 2 mc) ⁇ (R / S) ⁇ 2 ⁇ cos ⁇ (3)
- the weight moment of the pendulum m c to the swing center of the beam is:
- Mc— 0 and Mn— ⁇ are two inverse cosine curves. As long as the amplitudes are equal, there is Mn.
- the pendulum can directly balance the moment of inertia of the beam system; at this time, H must meet the equation
- H must be a real number, provided that
- the number of strokes n of the pumping unit defined by condition (7) is sufficient to meet actual needs.
- pendulum balance and any conventional balance method can fully balance the inertia force of the beam system within the beam, and obtain the best balance effect.
- the combination of the balance of the pendulum and the balance of the beam can generate a new kind of balance.
- the center of mass of the balanced mass is placed below the rear of the beam.
- the center of mass or the center of mass of the balanced mass has no relative movement with the beam.
- This new balance is called the "regular centroid under balance” (referred to as the under balance).
- the under balance there are also balancing methods that place the balance mass behind and behind the beam, but their center of mass / acting center of mass or regular relative movement to the beam as the pumping unit operates, or their center of mass / acting center of mass It is located on the center line of the beam and not below the beam. Therefore, the "under balance” mentioned here is substantially different from them.
- FIG. 24 The mass m of the center of mass on the walking beam 8 is located at G.
- the moment Mc generated by the swing center 0 of the walking beam in motion is composed of two parts. One part is the moment of gravity of m against 0, which is equal to the sagittal 0G and the gravity vector mg.
- the vector product of i is OGXmgi (i is the unit vector pointing to the center of the earth); the other part is the moment of inertia force of m against 0 when the beam is swinging, which is equal to the vector product of the tangential inertial force of the vector diameter 0G and m ⁇ ( ⁇ Is the angular acceleration of the beam 8 and ⁇ , T ⁇ 2 are unit tangential vectors perpendicular to 0G, 0B, 0C, respectively), so:
- Beam under beam balance and “Composite balance of beam balance and pendulum balance” are dynamically equivalent; or “Beam under balance can be dynamically and equally decomposed into beam component balance and Pendulum component balance”.
- the balance beam component and pendulum component under the balance beam are used to balance the gravity load of the pumping unit suspension point and the inertia force of the balance beam system, respectively. Both of these balances are essentially the transfer and storage of mechanical energy inherent in pumping units:
- the beam component is used to store the gravitational potential energy of the suspension mass Q:
- the crank can be lost from the top dead point (Q ⁇ ) to the bottom dead point ( ⁇ 0). Increase up to the maximum G 1; the crank goes from bottom dead center to top dead center, just the other way round. In this way, G ⁇ Gi ⁇ G ⁇ G, ... repeatedly cycle, the position of Q can be transferred and stored without loss, thus achieving the purpose of energy saving.
- the pendulum component is used to transfer and store the kinetic energy of the beam system:
- Suspension point load of the pumping unit mainly includes the weight of the pumping unit C and the weight of the lifted oil column Q 2 , and the inertia force of QQ 2 , followed by various factors (mainly friction, vibration and other factors) that prevent the movement of the sucker rod.
- the resistance F. Resistance work is always converted into heat and lost, and it is impossible to transfer and store it mechanically.
- the conventional crank balance and beam balance can transfer and store the C and Q 2 positions , but they cannot transfer and store their kinetic energy. Undoubtedly, the balance that allows Q 2 ’s position energy and kinetic energy to be fully transferred in both the up and down strokes and stored without loss will be the best balance for energy saving effects to reach the ideal state.
- the regulation of the center of mass under the balance is the best Good balance.
- Figures 26 and 27 can be proved: Figure 26 is the crank torque curve during the type test under the same load, and Figure 27 is the limit of the crank torque curve under the optimal balance state during the pumping operation under the same well condition and the same stroke.
- 1 A specified center-of-mass balance, and the strokes are the design strokes; (1—the conventional beam balance, the stroke is close to zero; 3 the conventional beam balance, the highest design stroke; 4—the corresponding inertia moment of 3. 1 is close to 2 and has nothing to do with the impulse, indicating that the inertia moment is completely balanced under the center of mass balance, and the peak value of 3 is much larger than 2 and 3 ⁇ 2 + 4, indicating that the conventional beam balance has no equilibrium inertia moment. Comparison of crank balance methods can have similar results.
Landscapes
- Engineering & Computer Science (AREA)
- Life Sciences & Earth Sciences (AREA)
- Geology (AREA)
- Mining & Mineral Resources (AREA)
- Physics & Mathematics (AREA)
- Environmental & Geological Engineering (AREA)
- Fluid Mechanics (AREA)
- General Life Sciences & Earth Sciences (AREA)
- Geochemistry & Mineralogy (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Structures Of Non-Positive Displacement Pumps (AREA)
Abstract
This invention relates to an oil pumping unit with a counterweight whose centroid can be adjusted comprising: a power supply (1), a belt transmission mechanism (3), a speed reducer (4), a crank (5), a connecting rod (6), a cross beam (10), a curved walking beam (8), a horsehead (9), a cable hanger (11), a post (14), a base (2) and a counterweight (15), characterized that the centroid of the counterweight (15) can be adjusted. According to one preferred embodiment of the invention, the counterweight (15) comprises at least two linking bars (22) in the front of the counterweight (15). The centroid of the counterweight (15) can be easily adjusted by attached one of the linking bars (22) in the front of the counterweight to the different hooks (23.1) on the end of the curved walking beam (8).
Description
规定质心下置平衡游梁抽油机 Required center-of-mass balanced beam pumping unit
1技术领域 1 technical field
本发明涉及用于石油矿场的下置平衡游梁抽油机。 The invention relates to a lower balanced beam pumping unit used in an oil field.
2发明背景 2 Background of the Invention
已取得国家发明专利的高效节能杆件抽油机 (专利号: 92115106. 3 ,授权日 99. 2. 10), 以及已取 得国家实用新型专利的平衡臂式两级平衡游梁抽油机(专利号: 96201421. 4 , 授权公告日: 98. 8. 26 ) , 都属于下置平衡游梁抽油机。 它们的缺点是: 不能根据实际要求调变下置平衡质量的下置距离 H, 更 不能在现场调变时测知 H的大小, 因此不能将 H规定为实际需要指定的数值, 而不能达到最佳平衡状 High-efficiency energy-saving rod pumping unit that has obtained national invention patents (patent number: 92115106. 3, authorization date: 99. 2. 10), and a balanced-arm two-stage balanced beam pumping unit that has obtained national utility model patents ( Patent number: 96201421. 4, Authorization announcement date: 98. 8. 26), all belong to the lower balance beam pumping unit. Their disadvantages are: the lower distance H of the lower balance mass cannot be adjusted according to the actual requirements, and the size of H cannot be measured during the on-site adjustment. Therefore, H cannot be specified as the value that actually needs to be specified, and it cannot reach the maximum value. Good balance
3本发明的简要说明 3 Brief description of the invention
本发明的目的, 是提供一种可根据油井井况和抽油机工况的实际需求, 将质心下置距离 H规定在 最佳位置的下置平衡游梁抽油机。 An object of the present invention is to provide a lower balanced beam pumping unit that can set the center of mass down distance H at an optimal position according to the actual requirements of the well conditions and pumping unit operating conditions.
此发明目的,由 "规定质心下置平衡游梁抽油机" 的技术方案来实现。 这个技术方案是在高效节 能杆件抽油机和平衡臂式两级平衡游梁抽油机专利技术的基础上加以改进而形成的, 主要在于: 采用 了具有规定质心结构的游梁下置平衡箱 /块, 描述如下: 一种规定质心下置平衡游梁抽油机, 包括动 力机 1 : 带传动装置 3 ; 减速机 4 ; 曲柄 5 ; 连杆 6 ; 横梁及横梁轴承座 10 ; 整体或组合弯游梁 ' 8; 游 梁支承 7 ; 片状或轮状驴头 9及挂在驴头上的悬绳器 11 ; 刹车装置 12 ; 支架 14; 底盘 2和安装在底 盘上的承冲装置 13 ; 以及联接在弯游梁尾端的游梁下置平衡装置, 也可有常规平衡, 其特征在于: 所 述游梁下置平衡装置是一种铰挂在弯游梁尾端的具有规定质心结构的下置平衡箱 /块。 The purpose of this invention is achieved by the technical solution of "prescribed centroid-centered balance beam pumping unit". This technical solution is improved on the basis of the patented technology of high-efficiency energy-saving rod pumping unit and balanced-arm two-stage balanced beam pumping unit. It mainly consists of: adopting the lower beam balance with a specified center of mass structure Boxes / blocks are described as follows: A type of under-centered balanced beam pumping unit, including power machine 1: belt drive 3; reducer 4; crank 5; connecting rod 6; cross beam and cross beam bearing block 10; integrated or combined Curved beam '8; beam support 7; sheet or wheel donkey head 9 and rope hanger 11 hanging on the donkey head; brake device 12; bracket 14; chassis 2 and impact bearing device 13 mounted on the chassis And a lower balance beam device connected at the tail end of the curved beam, which can also have a conventional balance, which is characterized in that: the lower balance beam device is a hinged hanging beam end with a specified center of mass structure Lower balance box / block.
由于游梁下置平衡具有规定质心的结构, 可在抽油机安装之时或在安装之前, 根据工况、 井况计 算所得数据, 将游梁下置平衡箱 /块的质心规定在最佳位置, 亦即将 H 凋变为指定的最佳数值, 获得 最好的平衡效果。 由于规定游梁下置平衡箱 /块质心的结构十分简单, 与常规游梁抽油机和现有下置 平衡游梁抽油机相比, 本发明抽油机兼有结构简单、 装拆方便、 节能效果显著的优点, 具体说: 结构 简单可靠, 成本低廉和维修装卸方便等更优于常规游梁抽油机: 使用性能更优于现有下置平衡游梁抽 油机。 Since the lower beam balance has a structure with a specified center of mass, the centroid of the lower beam balance box / block can be specified at the best when the pumping unit is installed or before the installation, based on the calculated data according to the working conditions and well conditions. Position, that is, H will decay to the specified optimal value to obtain the best balance effect. Because the structure of the lower balance box / block center of gravity of the beam is very simple, compared with the conventional beam pumping unit and the existing lower beam beam pumping unit, the pumping unit of the present invention has both simple structure and convenient assembly and disassembly. The energy saving effect has significant advantages, specifically: simple and reliable structure, low cost and convenient maintenance and disassembly are better than conventional beam pumping units: the performance is better than the existing lower balanced beam pumping units.
4附图的简要说明 4 Brief description of the drawings
本发明提供了众多实施方案, 通过下述实施例和附图作详细说明。 The present invention provides numerous embodiments, which are described in detail through the following examples and drawings.
图 1为实施例一的结构示意图。 FIG. 1 is a schematic structural diagram of the first embodiment.
图 2为实施例二的结构示意图。 FIG. 2 is a schematic structural diagram of the second embodiment.
图 3为实施例三的结构示意图。 FIG. 3 is a schematic structural diagram of the third embodiment.
图 4为实施例四的结构示意图。 FIG. 4 is a schematic structural diagram of a fourth embodiment.
图 5为作用质心调位块方案之一。 Figure 5 shows one of the solutions of the active mass centering block.
图 6为作用质心调位块方案之二。 Figure 6 is the second scheme of the active mass centering block.
确认本
图 7为作用质心调位块方案之三。 Confirm this Figure 7 is the third scheme of the active mass centering block.
图 8为作用质心调位块方案之四。 Figure 8 is the fourth scheme of the active mass centering block.
图 9为作用质心调位块方案之五。 Figure 9 is the fifth scheme of the active mass centering block.
图 10为作用质心调位块方案之六。 Figure 10 is the sixth scheme of the active mass centering block.
图 11为作用质心调位块方案之七。 Fig. 11 is the seventh scheme of the active mass centering block.
图 12为作用质心调位块方案之八。 Figure 12 shows the eighth solution of the center-of-mass positioning block.
图 13为实施例五的结构示意图。 FIG. 13 is a schematic structural diagram of the fifth embodiment.
图 14为伸缩轴实施方案之一。 Fig. 14 shows one embodiment of the telescopic shaft.
图 15为伸縮轴实施方案之二。 Figure 15 is the second embodiment of the telescopic shaft.
图 16为实施例六的结构示意图。 FIG. 16 is a schematic structural diagram of a sixth embodiment.
图 17为角度调节装置示意图。 Fig. 17 is a schematic diagram of an angle adjusting device.
图 18为框架式平衡箱结构方案之一。 Figure 18 is one of the structural schemes of the frame type balance box.
图 19为框架式平衡箱结构方案之二。 Figure 19 is the second structural scheme of the frame type balance box.
图 20为框架式平衡箱结构方案之三。 Figure 20 is the third structural solution of the frame type balance box.
图 21为框架式平衡箱结构方案之四。 Figure 21 is the fourth structural scheme of the frame type balance box.
图 22为三角曲柄示意图。 Figure 22 is a schematic diagram of a triangular crank.
图 23为摆锤平衡示意图。 Figure 23 shows the balance of the pendulum.
图 24为下置平衡游梁抽油机运动简图。 Figure 24 is a simplified diagram of the movement of the lower balanced beam pumping unit.
图 25为游梁复合平衡抽油机运动简图。 Figure 25 is a simplified diagram of the beam composite pumping unit.
图 26为本机与常规机的型式试验曲柄扭矩比较图。 Fig. 26 is a comparison chart of the crank torque of the type test of the machine and the conventional machine.
图 27为本机与常规机的抽油作业曲柄扭矩比较图。 Figure 27 compares the crank torque of the pumping operation between this machine and the conventional machine.
5本发明的较佳实施例 5 preferred embodiments of the present invention
图中: 1-动力机, 2-底盘, 3-带传动装置, 4-减速机, 5-曲柄, 6-连杆, 7-游梁支承, 8-游梁或 弯游梁, 8. 1-平衡臂, 9-驴头, 10-横梁及横梁轴承座, 11-悬绳器, 12-刹车, 13-承冲装置 14-上支架, 15- 下平衡箱, 16-上平衡箱, 17-立柱, 17. 1-横杆, 17. 2-加强板, 18-隔板, 19; 22-挂轴, 20; 21-吊耳, 23 -挂 座, 23. 1-U形挂钩, 24; 24. 1-靠 R, 25-楔形槽座, 26-直槽座, 26. 1一螺栓, 27-标尺, 28-挂 /铰轴, 29-平 衡箱 /块, 30-调位块, 30. 1-联接板, 30. 2-多齿卸荷盖板, 31-吊板或吊杆, 32-矩形轴承座,或与挂 /铰轴 联为一体的中部矩形轴段, 33-垫块, 34-螺栓, 35-螺母, 36-矩形槽, 37-矩形长槽, 38-矩形或梯形凸 齿, 39-矩形或梯形槽, 40-伸縮杆, 41-伸缩杆, 42-螺杆, 43-螺母, 44-嫘杆, 45-吊杆, 46-心管, 47-套 管, 48-带有右旋螺母的方管或园管,49-带有左旋螺母的方管或园管,50-双头左《右旋螺杆,51-底 板, 52-钩状 U形槽, 53-迷宫式 U形槽, 54-钩状矩形槽, 55-下支架, 56-支架, 57-辅助上、 下箱, 58- 壁架, 59-搁板, 60-角度调节架, 61-角度调节片, 62-整体式平衡箱, 63-框架立柱, 64-框架底板, 65 -框架顶板, 66-框架, 67-垫片, 68-辅助平衡箱。 In the picture: 1-power machine, 2-chassis, 3-belt transmission, 4-reducer, 5-crank, 6-link, 7-travel support, 8-travel or curved travel, 8. 1- Balance arm, 9-donkey head, 10-beam and beam bearing block, 11-rope suspension, 12-brake, 13-impact device 14-upper bracket, 15-lower balance box, 16-upper balance box, 17- Upright, 17. 1-cross bar, 17. 2-reinforcing plate, 18-partition, 19; 22-hanging shaft, 20; 21-lifting lug, 23-hanging seat, 23. 1-U-shaped hook, 24; 24. 1-by R, 25-wedge groove seat, 26-straight groove seat, 26. 1 one bolt, 27-scale, 28-hanging / hinge shaft, 29-balance box / block, 30-adjustment block, 30 1-connecting plate, 30. 2-multi-tooth unloading cover plate, 31-hanging plate or boom, 32-rectangular bearing seat, or middle rectangular shaft section integrated with the hanging / hinging shaft, 33-pad , 34-bolt, 35-nut, 36-rectangular slot, 37-rectangular slot, 38-rectangular or trapezoidal convex tooth, 39-rectangular or trapezoidal slot, 40-telescoping rod, 41-telescoping rod, 42-screw, 43 -Nuts, 44-Bars, 45-Booms, 46-Hearts, 47-Sleeves, 48-Square or round tubes with right-handed nuts, 49- Square or round tube with left-handed nut, 50-double-headed left-handed right-handed screw, 51-floor, 52-hook U-shaped groove, 53-maze U-shaped groove, 54-hook rectangular groove, 55-down Bracket, 56-bracket, 57-auxiliary upper and lower boxes, 58-wall shelf, 59-shelf, 60-angle adjustment stand, 61-angle adjustment piece, 62-integral balance box, 63-frame column, 64- Frame bottom plate, 65-frame top plate, 66-frame, 67-gasket, 68-auxiliary balance box.
(^游梁摆动中心, 0O "通过 0点与游梁平行的直线,称游梁作用线, G—下置平衡质量之质心或作
用质心 , L一质心或作用质心 G之后置距离, H -―质心或作用质心 G之下置距离, FF—平衡箱之中线或对 称面,与游梁作用线垂直, KK; JJ一分别在点 K或 J吊起平衡箱时之重垂线, R—曲柄长, S—游梁摆动中 心至横梁轴承中心之距离, Θ--曲柄转角,自下垂线起算,逆钟向为正, φ--游梁摆角,自指向驴头的水平 线起算,逆钟向为正。 (^ Swing center of beam, 0O "A straight line parallel to the beam through 0 point is called the beam action line, G—the center of mass or balance of the lower mass Use the center of mass, L-centroid or action center of mass G followed by the distance, H --- distance of center of mass or action center of mass G below, FF-center line or symmetry plane of the balance box, perpendicular to the beam line of action, KK; JJ- The heavy vertical line when the balance box is lifted at point K or J, R—the crank length, S—the distance from the swing center of the beam to the center of the beam bearing, Θ—the crank angle, counted from the droop line, the clockwise direction is positive, φ -You beam swing angle, counting from the horizontal line pointing to the donkey's head, the clockwise direction is positive.
实施例一.参看图 1 , 这是规定质心下置平衡游梁抽油机的基本模式之一。 其基本结构与现有下置 平衡游梁抽油机相同: 由动力机 1通过带传动装置 3和减速机 4减速后, 驱动装在减速机输出轴两端 的曲柄 5旋转, 再通过连杆 6 以及横梁和横梁轴承座 10, 带动弯游梁 8, 绕游梁支承的中心 0上下摇 摆, 装在弯游梁前端的驴头同步摇摆, 挂在驴头上的悬绳器就和抽油杆一起上下运动, 完成抽油工作, 本实施例的主要特征在于: 具有规定质心结构的游梁下置平衡装置, 是一种挂*靠在弯游梁尾端的具 有规定质心结构的游梁下置平衡箱, 规定质心结构包括两个部分: 一是调变质心结构, 二是测定质心 结构。 Embodiment 1. Referring to FIG. 1, this is one of the basic modes for specifying a balanced beam pumping unit under the center of mass. Its basic structure is the same as that of the existing lower balance beam pumping unit: After the power machine 1 is decelerated by the belt transmission 3 and the reducer 4, the cranks 5 installed at both ends of the reducer output shaft are driven to rotate, and then the connecting rod 6 and Crossbeam and crossbeam bearing block 10, which drives the curved beam 8 to swing up and down around the center 0 of the beam. The donkey head mounted on the front end of the curved beam synchronously swings, and the rope hanger hanging on the donkey head is connected with the sucker rod. The up and down movement completes the pumping work. The main feature of this embodiment is: a lower beam balancing device with a predetermined center of mass structure is a lower beam balancing with a predetermined center of mass hanging on the tail end of a curved beam The box specifies that the centroid structure includes two parts: one is to modulate the centroid structure, and the other is to determine the centroid structure.
调变质心结构采用了一种框架结构楼式平衡箱一用三至四根立柱 17 焊接上、 下底板构成一个框 架, 该框架将上平衡箱 16与下平衡箱 15联结为具有两个对称面的整体, 一个对称面与整机对称面重 合, 另一个对称面 FF与游梁作用线 00垂直; 并且上平衡箱 16和下平衡箱 15的上部均设置有至少一 块横向搁板 18, 并且上平衡箱 16 与下平衡箱 15 的侧面或底部均设置结构简单的排重门, 例如开一 个孔; 用插板控制孔的启闭。 增减上平衡箱 16和下平衡箱 15中重物的数量, 可使质心 G沿 FF移动, 达到调变质心下置距离 H的目的。 排重门用来卸去平衡质量。 隔板 18用来阻止平衡箱中的重物在抽 油机运转中滚动。 Modified center-of-mass structure adopts a frame structure floor balance box. One frame is welded with three to four uprights 17 to form a frame. The frame connects the upper balance box 16 and the lower balance box 15 to have two symmetrical planes. As a whole, one symmetry plane coincides with the whole machine symmetry plane, and the other symmetry plane FF is perpendicular to the beam action line 00; and the upper balance box 16 and the lower balance box 15 are each provided with at least one horizontal shelf 18 on the upper side, and the upper The side or bottom of the balance box 16 and the lower balance box 15 are provided with a simple structure of a weight-removing door, for example, opening a hole; the opening and closing of the hole is controlled by a plug board. Increasing or decreasing the number of weights in the upper balance box 16 and the lower balance box 15 can make the center of mass G move along FF to achieve the purpose of adjusting the distance H under the center of mass. The heavy-duty door is used to unbalance the mass. The partition 18 is used to prevent the weight in the balance box from rolling during the operation of the pumping unit.
测定质心结构是楼式平衡箱的挂轴 ·标尺结构和包容结构一挂轴 ·标尺结构是: 楼式平衡箱的前、 后侧面上设置有挂轴 19、 22——前、 后侧面各联有一对吊耳 20、 21 , 吊耳中穿有挂轴 19、 22; 或在 立柱 17上开孔直接穿有挂轴 19、 22; 也可将挂轴 19、 22焊接或用螺栓联接在立柱上, 挂轴中央制有 容纳起吊钢丝绳的沟槽, 前后两侧挂轴在楼式平衡箱的高度方向错开一个距离, 楼式平衡箱通过挂轴 铰 /挂在弯游梁尾端的挂座 23或挂钩 23. 1上。 并且, 楼式平衡箱的左 /右侧面中线 FF处, 置有自游 梁作用线起算的标尺 27。 所述包容结构是楼式平衡箱前侧两根立柱 17在整机对称面垂直方向的间距 大于弯游梁尾端的宽度, 以便现场测定平衡装置质心时弯游梁尾端可伸进立柱间的空档; 同时在立柱 17和弯游梁尾端之间设置靠闩 24: 抽油机工作时楼式平衡箱通过靠闩靠牢在弯游梁尾端, 调平衡时 取去或退出靠闩, 楼式平衡箱处于自由饺挂状态。 靠闩有多种安装方式, 本实施例采用楔块升降结构: 平衡箱内侧固结一对向上开口的直槽座 26, 直槽中滑配靠闩 24, 拧转直槽座底部螺栓 26. 1或在靠闩 24与直槽座底面间打入楔片, 将靠闩 24向上挤入楔形槽座 25的楔形槽中, 楔形槽座 25与弯游梁尾 端联为一体并向下开口, 靠闩 24的截面下半为矩形, 上半为楔形。 也可采用靠闩联接结构: 靠闩 24 置于直槽座 26 的槽中, 用螺栓与弯游梁尾端牢固联接。 还可采用勾头结构, 弯游梁尾端有一个向上 开口的勾头, 勾头中置有一根靠闩 24, 抽油机工作时楼式平衡箱前侧与靠闩相靠, 还可用螺栓将它们 连接在一起。
吊起挂轴 19或 22时, 重垂线 KK和 JJ必经过平衡装置的质心 G; 楼式平衡箱关于 FF对称, G又 在 FF上, 故 KK; JJ; FF必汇交于 G。 有两种测定 G的方法: 一种是在挂轴 19或 22的中央吊起楼式 平衡箱, 通过挂轴中心的重垂线 KK或 JJ, 和 FF的交点, 就是质心 G; 另一种是楼式平衡箱通过挂轴 19或 22铰挂在弯游梁尾端的挂座 23或 U形挂钩 23. 1上,抽去或退出靠闩 24,弯游梁尾端伸进立柱 17 间的空档, 楼式平衡箱处于自由悬挂状态, 相应重垂线与 FF的交点就是质心 G。 在标尺 27上可读出 楼式平衡箱质心下置距离 H, 同时利用调变质心位置结构将它调变到符合要求。 前一种方法用于装机 前的准备工作; 后一种方法用于装机时细调或更换冲次、 冲程时调节平衡, 可不用吊车。 The measurement center of mass structure is the hanging shaft of the floor balance box. The scale structure and the containment structure. The hanging shaft and the scale structure are: The front and rear sides of the floor balance box are provided with hanging shafts 19 and 22. There are a pair of lifting ears 20 and 21, and hanging shafts 19 and 22 are worn in the lifting ears; or holes 19 and 22 are directly worn on the posts 17; the hanging shafts 19 and 22 can also be welded or bolted to the posts In the center of the hanging shaft, a groove for suspending the wire rope is made. The front and rear hanging shafts are staggered by a distance in the height direction of the floor balance box. The floor balance box is hinged / hanged on the hanging end of the bending beam 23 through the hanging shaft. Or hook on 23.1. In addition, at the left / right side center line FF of the floor balance box, a scale 27 is set from the beam action line. The containment structure is that the distance between the two vertical columns 17 on the front side of the building balance box in the vertical direction of the plane of symmetry of the whole machine is greater than the width of the tail end of the bending beam, so that when measuring the center of mass of the balancing device, the tail end of the bending beam can extend into the column. Neutral; At the same time, a bolt 24 is provided between the column 17 and the tail end of the bending beam. The floor balance box is fixed to the tail end of the bending beam by the bolt when the pumping unit is in operation. When the balance is adjusted, the bolt is removed or exited. The floor balance box is in a free dumpling hanging state. There are various installation methods for the latch, and this embodiment adopts a wedge lifting structure: the inside of the balance box is fixed with a pair of straight slot seats 26 which are opened upward, and the straight slot is provided with the latch 24, and the bottom bolt 26 of the straight slot seat is rotated. 1 Or drive a wedge between the latch 24 and the bottom surface of the straight slot seat, and squeeze the latch 24 upward into the wedge slot of the wedge slot seat 25. The wedge slot seat 25 is integrated with the tail end of the bending beam and opens downward. The lower half of the cross section of the latch 24 is rectangular, and the upper half is wedge-shaped. It can also be connected by the bolt: the bolt 24 is placed in the groove of the straight groove seat 26, and it is firmly connected with the tail end of the bending beam by bolts. A hook head structure can also be used. The tail end of the bending beam has a hook head that opens upward. A hook bolt 24 is placed in the hook head. The front side of the balance box of the pumping unit works against the bolt when the pumping unit is working. Bolts can also be used Connect them together. When the hanging shaft 19 or 22 is lifted, the heavy vertical lines KK and JJ must pass through the center of mass G of the balancing device; the floor balance box is symmetrical about FF, and G is on FF, so KK; JJ; FF must meet G. There are two methods for determining G: one is to lift the floor balance box in the center of the hanging shaft 19 or 22, and the intersection point of the vertical line KK or JJ with the center of the hanging shaft and FF is the center of mass G; the other is The floor balance box is hinged on the hanging seat 23 or U-shaped hook 23.1 at the tail end of the bending beam through the hanging shaft 19 or 22, and the bolt 24 is removed or withdrawn, and the tail end of the bending beam extends into the column 17 In neutral, the floor balance box is in a free hanging state, and the intersection of the corresponding heavy vertical line and FF is the center of mass G. On the scale 27, the distance H below the center of mass of the building balance box can be read, and at the same time, it can be adjusted to meet the requirements by adjusting the position of the center of mass. The former method is used for preparation before installation; the latter method is used for fine adjustment or replacement of strokes and balance during stroke, without crane.
本实施例采用联为一体的弯游梁, 也可采用由平衡臂 8. 1与游梁联接而成的组合弯游梁。 In this embodiment, a curved bending beam is used as a whole, and a combined curved beam formed by connecting a balance arm 8.1 to the bending beam may also be used.
实施例二。 参看图 2, 本实施例与实施例一比较, 主要区别在于所述规定质心结构是一种多挂轴 / 钩平衡箱。 多挂轴平衡箱是: 平衡箱 15 制成独立的整体矩形结构, 其前; 后两侧错距布置有至少三 根挂轴, 这些挂轴或通过吊耳 20; 21 与平衡箱前后侧面相联, 或直接穿在平衡箱左右侧面的孔中, 平衡箱通过这些挂轴之一铰挂在与弯游梁尾端联为一体的挂座 23或 U形挂钩 23. 1上。 吊起挂轴 19 或 22, 相应重垂线 KK; JJ与平衡箱对称线 FF汇交于 G, 就可从标尺 27上读出 G的下置距离 H; 更换 挂轴可调变质心 G 的下置距离 H, H将按挂轴间的错距增大或减小。 抽油机工作时, 平衡箱前侧面通 过靠闩 24. 1 靠牢在弯游梁尾端, 靠闩可与弯游梁尾端联为一体, 并与平衡箱用螺栓联住, 也可采用 实施例一所述联接方式。 多挂钩平衡箱与多挂轴平衡箱的区别是: 挂钩装在平衡箱上, 挂轴装在弯游 梁尾端。 ' 实施 例 二。 Second embodiment. Referring to FIG. 2, this embodiment is compared with the first embodiment, and the main difference is that the specified center of mass structure is a multi-hanging shaft / hook balance box. The multi-hanging balance box is: The balance box 15 is made of an independent overall rectangular structure, and its front; at least three hanging shafts are arranged at different distances on the rear sides, and these hanging shafts are connected to the front and back sides of the balance box through lifting eyes 20; 21 1 , Or directly through the holes on the left and right sides of the balance box, the balance box is hinged on one of these hanging shafts on the pedestal 23 or U-shaped hook 23.1 linked to the end of the bending beam. Lift the hanging shaft 19 or 22, corresponding to the heavy vertical line KK; JJ and the balance box symmetrical line FF meet at G, then the lower distance H of G can be read from the scale 27; the hanging shaft can be adjusted to change the center of mass G The lower distance H, H will increase or decrease according to the misalignment between the hanging shafts. When the pumping unit is in operation, the front side of the balance box is fastened to the tail end of the bending beam by the bolt 24. 1. The bolt can be integrated with the tail end of the bending beam and bolted to the balance box. It can also be used The connection mode is described in the first embodiment. The difference between a multi-hook balance box and a multi-hook balance box is: The hook is installed on the balance box, and the hanging shaft is installed at the end of the bending beam. '
本实施例的另一个特点是采用了塔式双层支架结构: 整个支架由上支架 14和下支架 55用螺栓联 接而成, 下支架 55可与底盘焊联为一体, 也可用螺栓联接; 上支架 14设计成整体钢结构或与现有结 构相仿的装配式三角撑, 用螺栓联接在下支架上。 这种支架结构的优点, 是整机刚性好, 并且便于运 输。 本发明和现在广泛使用的常规游梁抽油机, 都可采用这种支架结构。 Another feature of this embodiment is the use of a tower double-layer bracket structure: the entire bracket is formed by bolting the upper bracket 14 and the lower bracket 55, and the lower bracket 55 can be welded to the chassis as a whole or can be bolted together; The bracket 14 is designed as an integral steel structure or an assembled triangular brace similar to the existing structure and is bolted to the lower bracket. The advantage of this bracket structure is that the whole machine has good rigidity and is easy to transport. Both the present invention and the conventional beam pumping unit widely used now can adopt such a bracket structure.
实施例一也可采用这里所说的多挂轴 /挂钩结构和塔式双层支架结构。 The first embodiment may also adopt the multi-hanging shaft / hook structure and the tower double-layer support structure described herein.
实施例三。 参看图 3, 它与实施例二的区别在于: 平衡箱 15上部用两根立柱 17, 上焊横杆 17. 1, 旁焊加强板 17. 2,延伸出一个挂背; 也可用四根立柱上加顶板, 在平衡箱上部延伸出一个框架结构; 构成挂背或框架结构的立柱上设置有至少三根挂轴 22, 这些挂轴穿在立柱 17的孔中, 或焊接或用螺 栓联接在立柱 17 上, 也可通过吊耳装在立柱的前侧面上。 当然也可将挂轴装在弯游梁尾端, 构成挂 背或框架结构的立柱上则装有挂钩。 Embodiment 3. Referring to FIG. 3, it is different from the second embodiment in that: the upper part of the balance box 15 uses two columns 17, an upper welding cross bar 17.1, and a side welding reinforcing plate 17.2, extending a hanging back; four columns can also be used A top plate is added on top, and a frame structure is extended on the upper part of the balance box; at least three hanging shafts 22 are arranged on the posts constituting the hanging back or the frame structure, and these hanging shafts pass through the holes of the column 17 or are welded or bolted to the columns 17 can also be mounted on the front side of the column through the lifting ears. Of course, the hanging shaft can also be installed at the tail end of the curved beam, and the post constituting the hanging back or the frame structure is provided with a hook.
实施例四。 参看图 4, 这是规定质心下置平衡游梁抽油机的基本模式之二, 它与前述实施例的区 别, 在于下置平衡箱 /块与弯游梁尾端采用了自由铰挂 构, 规定质心结构采用了调位块 ·平衡箱 /块 铰挂系统一调位块 30直接或通过联接板 30. 1联接在弯游梁 8的尾端或与之联为一体, 平衡箱 /块 29 向上延伸出两个对称的吊板或吊杆 31 , 图示位置, 调位块 30与吊板 31的对称线相重合, 在此对称 线 FF上, 调位块 30和吊板 31均制有同等数量、 同等间距的孔系。 挂 /铰轴 28穿入孔系的某一孔中, 平衡箱 /块 29就在此孔位与调位块 30自由铰接, 该孔位中心 G就是铰接点; 因为平衡箱 /块的整个重 量都要通过铰接点 G作用在游梁上, 实际质心将不起作用, 其平衡效果与平衡箱 /块整个重量全部集
中在铰接点 G相同, 所以该铰接点 G叫做下置平衡装置的作用质心, L和 H分别是 G的后置距离和下 置距离。 挂 /铰轴 28穿在不同的孔中, 同一个平衡箱 /块就有不同的 H; 还可在调位块 30上制有多列 孔系, 同时调变 H和 L。 如果备有二根挂 /铰轴 28, 按规定质心位置穿装好挂 /铰轴, 再拆下前一根挂 /铰轴, 调变工作将十分方便。 Embodiment 4. Referring to FIG. 4, this is the second basic mode of specifying a center-center underbalanced beam pumping unit, which is different from the foregoing embodiment in that a free hinge structure is adopted at the lower end of the balance box / block and the end of the beam. Provided that the center of mass structure adopts an adjustment block, balance box / block hinge system, an adjustment block 30 directly or through a connecting plate 30. 1 is connected to the tail end of the curved beam 8 or integrated with it, the balance box / block 29 Two symmetrical suspenders or suspenders 31 are extended upward. At the position shown in the figure, the alignment block 30 and the symmetric line of the suspender 31 coincide. On this symmetric line FF, the aligner 30 and the suspender 31 are made with Equal number of holes with equal spacing. The hanging / hinging shaft 28 penetrates into a certain hole in the hole system, and the balance box / block 29 is freely hinged at this hole position with the adjustment block 30. The center G of the hole position is the hinge point; because the entire weight of the balance box / block Must act on the beam through the hinge point G, the actual center of mass will not work, its balance effect and the entire weight of the balance box / block are all set The hinge point G is the same at middle, so the hinge point G is called the active center of mass of the lower balance device, and L and H are the rear and lower distances of G, respectively. The hanging / hinging shaft 28 is worn in different holes, and the same balance box / block has different H; it is also possible to make multiple rows of hole systems on the adjustment block 30, and adjust H and L at the same time. If there are two hanging / hinging shafts 28, put on the hanging / hinging shaft according to the specified center of mass position, and then remove the previous hanging / hinging shaft, the adjustment work will be very convenient.
调位块的实施方案多种多样, 图 5〜图 12是部分例子。 There are various embodiments of the positioning block, and some examples are shown in Figs. 5 to 12.
图 5是一种钩状 U形槽铰挂结构: 调位块 30右侧通过同其联为一体的联接板 30. 1与弯游梁尾端 悍牢或用螺栓固联, 左侧制有至少三个钩状 U形槽 52 , 平衡箱铰挂在钩状 U形槽中: 平衡箱 29左右 两侧向上延伸出吊板 31, 两块吊板上端制有同心园孔, 孔中装有轴承, 挂 /铰轴 28穿在轴承中并作相 对轴向固定, 其中部轴段置于钩状 U形槽中。 钩状 U形槽底部半园的中心就是平衡质量的作用质心, 因为至少有三个钩状 U形槽, 就至少有三个下置距离 H可供选择, 以适应抽油机三种冲次的平衡要求。 Figure 5 is a hook-shaped U-shaped groove hinge structure: the right side of the adjustment block 30 is connected with the connecting plate 30. 1 with the end of the bending beam firmly or bolted, the left side is made At least three hook-shaped U-shaped grooves 52, the balance box is hinged in the hook-shaped U-shaped groove: The left and right sides of the balance box 29 extend upward from the hanging plate 31, and the two hanging plates are provided with concentric circular holes at the top, and the holes are provided with In the bearing, the hanging / hinging shaft 28 is penetrated in the bearing and fixed relatively axially, and the middle shaft section is placed in the hook-shaped U-shaped groove. The center of the bottom half circle of the hook-shaped U-shaped groove is the center of mass for balancing the mass. Because there are at least three hook-shaped U-shaped grooves, there are at least three lower distances H to choose from to suit the balance of the three strokes of the pumping unit. Claim.
所说钩状 U形槽也可改为与弯游梁尾端或调位板铰接的吊钩, 吊钩的内侧可采用 U形, 也可采用 矩形, 这时吊钩与调位块或游梁尾端的铰接点为作用质心。 这种结构可叫做吊钩 ·平衡箱 /块铰挂系统。 The hook-shaped U-shaped groove can also be changed to a hook that is hinged to the end of the curved beam or the positioning plate. The inside of the hook can be U-shaped or rectangular. At this time, the hook and the positioning block or swim The hinge point at the end of the beam is the acting center of mass. This structure can be called a hook-balance box / block hinge system.
图 6是一种迷宫式 U形槽铰挂结构: 它与图 5的区别在于, 调位块 30上制有多排横向通道, 每 排通道下垂多个 U形槽, 称为迷宫式 U形槽 53, 并且每个通道的进口都用多齿卸荷盖板 30. 2封住, 多 齿卸荷盖板用螺栓固联在调位块上。 调位块采用这一方案, 作用质心 G的后置距离 L和下置距离 H均 可调变。 FIG. 6 is a labyrinth U-shaped groove hinge structure: It is different from FIG. 5 in that the positioning block 30 is provided with multiple rows of lateral channels, and each row of channels hangs multiple U-shaped grooves, which is called a labyrinth U-shape The slot 53 and the entrance of each channel are sealed with a multi-tooth unloading cover plate 30.2, and the multi-tooth unloading cover plate is bolted to the positioning block. The positioning block adopts this scheme, and both the rear distance L and the lower distance H acting on the center of mass G are adjustable.
图 7是一种矩形槽铰挂结构:' 调位块 30上制有至少三个矩形槽 36, 挂 /铰轴 28通过吊杆 31与调 位块 30在矩形槽中挂 /铰。 有两种挂 /铰方式一 ( 1 ) 挂 /铰轴 28中段与外廓为矩形的轴承座 32铰接, 该矩形外廓轴承座置于调位块的矩形槽中, 吊杆 31 上端活套在挂 /铰轴 28两端, 下端与联接在平衡 箱 /块 29左右侧的轴头活套, 并作轴向固定。 (2 ) 吊杆 31上端与挂 /铰轴 28两端通过轴承铰接, 挂 / 铰轴 28中部为矩形轴段 32, 该矩形轴段置于调位块 30的矩形槽中。 调位块 30的矩形槽用带齿的卸 荷盖板 30. 2封住。 矩形轴承座或与挂 /铰轴联为一体的中部矩形轴段 32 的中心, 就是平衡装置的作 用质心, 它到游梁作用线 00的距离则是其下置距离 H。 Figure 7 is a rectangular slot hinge structure: 'The positioning block 30 is provided with at least three rectangular slots 36, and the hanging / hinging shaft 28 is hung / hinged in the rectangular slot through the suspension rod 31 and the adjusting block 30. There are two ways of hanging / hinging. (1) The middle section of the hanging / hinging shaft 28 is hinged with a rectangular bearing housing 32, which is placed in the rectangular groove of the adjusting block, and the upper end of the boom 31 is a looper. At both ends of the hanging / hinging shaft 28, the lower ends are connected to the shaft head loopers connected to the left and right sides of the balance box / block 29, and are axially fixed. (2) The upper end of the suspender 31 and the two ends of the hanging / hinging shaft 28 are hinged through bearings. The middle of the hanging / hinging shaft 28 is a rectangular shaft section 32, which is placed in a rectangular groove of the positioning block 30. The rectangular groove of the positioning block 30 is sealed with a toothed unloading cover 30.2. The center of the rectangular bearing block or the middle rectangular shaft section 32 integrated with the hanging / hinge shaft is the center of mass of the balancing device, and the distance from the beam action line 00 is its lower distance H.
图 8是一种钩状矩形槽铰挂结构, 它与图 7的区别是: 调位块 30上的矩形槽改为钩状矩形槽 54。 调位块采用本方案, 装卸操作将与图 5—样方便。 FIG. 8 is a hook-shaped rectangular slot hinge structure. The difference from FIG. 7 is that the rectangular slot on the positioning block 30 is changed to a hook-shaped rectangular slot 54. The positioning block adopts this scheme, and the loading and unloading operations will be as convenient as in Figure 5.
图 9是一种长槽铰挂结构, 它与图 7矩形槽铰挂结构的区别在于: (1 ) 调位块上的多个矩形槽改 为向上幵口或不开口的矩形长槽 37, 开口长槽的上端用螺栓 34螺母 35拉住, 以增强调位块强度, 并对挂 /铰轴或矩形外廓轴承座起夹持作用。 (2 )矩形轴承或与挂 /铰轴 28联为一体的中部矩形轴段 32 置于所说长槽中, 长槽底部置有厚薄不等的垫块 33 , 用来调变作用质心的位置和下置距离?1。 垫块 33 中还可包括一个带 U形槽的墊块, 用来在矩形槽中置放园形挂 /铰轴。 中间构件 31采用吊板, 也可采 用吊杆。 所说长槽至少是一个也可以是平行的 2~3个。 FIG. 9 is a long-slot hinge structure, which is different from the rectangular-slot hinge structure of FIG. 7 in that: (1) the plurality of rectangular grooves on the positioning block are changed to rectangular long grooves 37 which are open or not open, The upper end of the open long slot is pulled with bolts 34 and nuts 35 to enhance the strength of the positioning block and to clamp the hanging / hinge shaft or rectangular outline bearing seat. (2) A rectangular bearing or a middle rectangular shaft section 32 integrated with the hanging / hinging shaft 28 is placed in the long groove, and a pad 33 of varying thickness is placed at the bottom of the long groove to adjust the position of the acting center of mass. Distance from the bottom? The spacer 33 may further include a spacer with a U-shaped groove for placing a circular hanging / hinge shaft in a rectangular groove. The intermediate member 31 is a suspension plate or a suspension rod. The long groove is at least one or two or three parallel grooves.
图 10是一种由螺杆 42和螺母 43联接成的简易千斤顶, 用它代替图 9长槽底部的垫块, 可无级 调变作用质心的下置距离 H。 Fig. 10 is a simple jack connected by a screw 42 and a nut 43. It can be used instead of the spacer at the bottom of the long groove in Fig. 9 to continuously adjust the lower distance H of the center of mass.
图 11也是一种长槽铰挂结构, 只是调位块 30上的长槽 37封闭或向下开口, 调位块顶部设置了
螺杆" 累母机构, 螺杆 44上端带有拧转用方头, 下端与矩形轴承座或矩形轴段 32沿螺杆轴向相联; 平衡箱通过吊杆 45铰吊在从矩形轴承座 32两侧伸出, 或从矩形轴段 32向两侧延伸的挂 /铰轴 28上。 这种调位块方案可连续调变作用质心 G的下置距离 H, 但要防止螺杆螺母锈死。 FIG. 11 is also a long-slot hinge structure, except that the long slot 37 on the positioning block 30 is closed or opened downward, and the top of the positioning block is provided with "Screw" tired mother mechanism, the upper end of the screw 44 is provided with a square head for rotation, and the lower end is connected to the rectangular bearing seat or the rectangular shaft section 32 in the axial direction of the screw; the balance box is hung on both sides of the rectangular bearing seat 32 through the suspension rod 45 Extend or extend from the rectangular shaft section 32 to both sides of the hanging / hinge shaft 28. This positioning block scheme can continuously adjust the lower distance H of the center of mass G, but prevent the screw nut from rusting.
图 12是调位块 30与弯游梁尾端的一种联接方案:有一个联接板 30. 1,其上有矩形或梯形凸齿 38, 调位块 30的内侧开有相应的矩形或梯形槽 39与之相卡, 并且调位块 30上部用螺栓 34螺母 35与联 接板 30. 1 固联, 联接板则与弯游梁尾端联为一体。 采用这种联接方案, 也可调变作用质心的下置距 离 H, 而作为调位块的调位方案。 FIG. 12 is a connection scheme between the positioning block 30 and the end of the bending beam: there is a connecting plate 30.1, which has rectangular or trapezoidal convex teeth 38, and the inside of the positioning block 30 has a corresponding rectangular or trapezoidal groove. 39 is engaged with it, and the upper part of the adjusting block 30 is fixedly connected with the connecting plate 30. 1 by bolts 34 and nuts 35, and the connecting plate is integrally connected with the tail end of the bending beam. With this connection scheme, the downward distance H of the acting center of mass can also be adjusted, and it can be used as the positioning scheme of the positioning block.
必须指出: 调位块 30 可是块状, 也可是板状, 条状或中空结构。 它可以是与弯游梁尾端联接的 —个独立体: 也可以与弯游梁尾端联为一体一这时, 调位块可视为弯游梁尾端, 在调位块上制有孔; 槽, 就是在弯游梁尾端上制有孔、 槽。 所说吊杆 31 可是板状、 杆状、 条状、 也可是义状或两头是义 状。 It must be pointed out that the positioning block 30 can be block-shaped, plate-shaped, strip-shaped or hollow structure. It can be connected to the end of the bending beam-an independent body: it can also be integrated with the end of the bending beam. At this time, the adjustment block can be regarded as the end of the bending beam. Holes and grooves are holes and grooves made at the end of the curved beam. The suspension rod 31 may be plate-shaped, rod-shaped, strip-shaped, or meaning-shaped, or both ends may be meaning-shaped.
实施例五。 参看图 13 , 这是规定质心下置平衡游梁抽油机的基本模式之三, 规定质心结构下置平 衡装置采用了三角桁架*平衡箱 /块铰 /挂系统一伸缩杆 40; 41上端分别和游梁 8铰接, 下端相互铰接, 构成一个可调变的三角桁架式的弯游梁, 平衡箱 /块 29直接或通过挂杆 /挂钩自由铰 /挂在三角桁架下 部铰接点 G处。 G就是下置平衡装置的作用质心。 因为 40与 41均为长度可调变的伸缩杆, 可根据实 际要求将 G调变到设计范围内的任何规定位置。 伸缩杆 40; 41与游梁 8的铰接点不一定是在图 13所 示位置, 也可以在其他位置与游梁铰接, 还可用螺栓将铰接支座联接在游梁上部、 下部或尾端, 并带 有调位结构。 如果平衡块 29制成圆形或矩形, 还可令其质心与铰接中心重合而铰挂在铰接轴 G上, 实施例四也可这样。 Embodiment five. Referring to FIG. 13, this is the third of the basic modes of specifying the center-of-center balanced beam pumping unit. It is specified that the center-of-center structure of the under-balanced device adopts a triangular truss * balance box / block hinge / hanging system with a telescopic rod 40; 41 It is articulated with the beam 8 and the lower ends are articulated with each other to form an adjustable triangular truss-type curved beam. The balance box / block 29 is freely hinged / hanged directly or at a hinge point G on the lower part of the triangle truss directly or through a hanging rod / hook. G is the working center of mass of the lower balancing device. Because 40 and 41 are telescopic rods with adjustable length, G can be adjusted to any specified position within the design range according to actual requirements. The articulation points of the telescopic rods 40; 41 and the beam 8 are not necessarily in the position shown in FIG. 13, but can also be hinged with the beam in other positions, and the hinge support can be bolted to the upper, lower or tail end of the beam, And with an alignment structure. If the balance block 29 is made into a circle or a rectangle, the center of mass of the balance block 29 can also coincide with the hinge center and can be hung on the hinge axis G. The fourth embodiment can also do the same.
图 14是伸縮杆方案之一: 心管 46 与套管 47滑套, 套管上制有至少一个园孔, 心管上则制有一 系列园孔, 螺杆 34插入套管及心管的不同孔中, 即可调变伸缩轴的长度, 此长度可从刻在心管上的 标尺 27读出。 Figure 14 is one of the telescopic rod solutions: a sliding sleeve of a core tube 46 and a sleeve 47, the sleeve is provided with at least one circular hole, the core tube is made with a series of circular holes, and the screw 34 is inserted into the different holes of the sleeve and the core tube. Medium, that is, the length of the telescopic shaft can be adjusted, and this length can be read from the scale 27 engraved on the heart tube.
图 14是伸缩杆方案之二: 带有右旋或左旋螺母的方管或园管 48、 49, 用一种双头左《右旋螺杆 50 将它们联接起来, 可构成另一种伸缩杆, 双头左《右旋螺杆 50的凹槽中还刻有显示伸缩杆长度的标尺 27。 Figure 14 is the second solution of the telescopic rod: square or circular tubes 48, 49 with right-handed or left-handed nuts, and they are connected by a double-headed left-handed right-handed screw 50 to form another telescopic rod. The groove of the double-headed left-handed right-hand screw 50 is also engraved with a scale 27 indicating the length of the telescopic rod.
实施例六。 参看图 16 , 这是规定质心下置平衡游梁抽油机的基本模式之四, 特点是用摆动方式调 变平衡装置质心下置距离 H: 弯游梁采用平衡臂 8. 1挂靠在游梁 8尾部的组合结构, 并且在相靠处安 装角度调节装置 A; 同时平衡箱 62与平衡臂 8. 1之尾端也采用挂靠结构, 相靠处安装与 A相同的角度 调节装置 B, 调变 A、 B中角度调节片之数量, 但保持其总数不变, 可使平衡臂 8. 1与游梁 8的夹角 α 发生变化, 平衡箱 62与游梁 8夹角 Ρ则始终恒定而达到调变 Η的目的。 角度装置 Α、 Β放大如图 17所 示, 它由安装架 60与角度调节片 61组成, 安装架的弧面与角度调节片 61之外园有相同的直径 d, 并 都以铰挂轴中心 0为圆心, 角度调节装置 A、 B中的调节元件也可不用角度调节片, 改用调节块、 销 轴、 螺杆千斤顶等。 角度调节装置 B还可安装在特制的靠闩 24上, 称角度调节靠闩, 此时角度调节 装置 A可单独置入平衡臂 8. 1与游梁 8尾端的相靠处, 也可制成角度调节靠闩置入。
本发明平衡箱结构形式多样, 有整体分层结构、 框架结构、 挂背结构与自由铰接结构等等。 整体 分层结构 62 (图 16) 是将平衡箱制成一个整体, 内部还可设计支架 56或壁架 58, 安放搁板 59, 还 可在整体平衡箱上、 下部座入或联接辅助上、 下箱 57。 框架式的基本结构如图 18~21 所示, 是用三 根或四根等长立柱 63联接顶板 65和底板 64构成框架 66, 框架上部联接上箱 16 (图 19) 或联接下箱 15 (图 20 ), 或同时联接有上箱和下箱 (图 18), 下箱底部还可再联下箱。 所述联接可以是常用的螺 栓联接, 也可以是联为一体的焊接, 框架内部还可采取惯用手段滑配辅助平衡箱 68 (图 21 ), 并采取 惯用的提升或举升装置调节该辅助平衡箱的位置后加以固定。 挂背结构 (图 3 ) 是框架结构的一个变 种, 在无需设置上箱时采用。 自由铰接结构如图 4~13 所示, 制作要求较高, 从驴头一端看去, 平衡 箱 /块必须左右对称。 不论是何种结构, 平衡箱 /块的下部还可联接多个辅助下箱 /块, 并且最下部平 衡箱 /块的顶面设置有厚度不小于 5~10 毫米的垫片 67, 将所述下箱卸在承冲装置上, 取去垫片, 抽 油机可正常运转而不会与卸下的箱顶碰撞, 取去的垫片复位又可将辅助下箱重新眹接在平衡装置上。 这种结构将有利于初装运转时减轻电机负荷并有利于 "碰泵"等作业。 Embodiment 6. Referring to FIG. 16, this is the fourth of the basic modes for specifying a balanced beam pumping unit under the center of mass, which is characterized by using a swing method to adjust the distance under the center of mass of the balancing device H: The curved beam uses a balance arm 8.1. 8 tail combined structure, and angle adjustment device A installed at the abutment; At the same time, the tail end of the balance box 62 and the balance arm 8.1 also adopt a hanging structure, the same angle adjustment device B is installed at the abutment, adjusted The number of angle adjustment plates in A and B, but keeping the total number unchanged, can make the angle α between the balance arm 8.1 and the beam 8 change, and the angle P between the balance box 62 and the beam 8 is always constant to reach Modulate the purpose of Η. The angle devices A and B are enlarged as shown in FIG. 17. It is composed of a mounting bracket 60 and an angle adjusting piece 61. The arc surface of the mounting frame and the angle adjusting piece 61 have the same diameter d, and both are centered on the hinge axis. 0 is the center of the circle, and the adjustment elements in the angle adjustment devices A and B can also be replaced by an adjustment block, a pin, a screw jack, etc. without using an angle adjustment piece. The angle adjustment device B can also be installed on a special backrest bolt 24, which is called an angle adjustment backrest. At this time, the angle adjustment device A can be separately placed into the abutment of the balance arm 8.1 and the tail end of the beam 8, or it can be made. The angle adjustment is inserted by the latch. The balance box structure of the present invention has various forms, including an overall layered structure, a frame structure, a back hanging structure, a free hinge structure, and the like. The overall layered structure 62 (Fig. 16) is a balance box made into a whole. The interior can also be designed with a bracket 56 or a wall frame 58, and a shelf 59. It can also be seated on the overall balance box, connected to the lower part, or connected to an auxiliary, Under the box 57. The basic structure of the frame is shown in Figs. 18-21. Three or four equal-length posts 63 are used to connect the top plate 65 and the bottom plate 64 to form a frame 66. The upper part of the frame is connected to the upper box 16 (Figure 19) or the lower box 15 (Figure 19). 20), or an upper case and a lower case are connected at the same time (Figure 18), and the lower case can be connected to the lower case. The connection may be a commonly used bolt connection or a joint welding. The frame can also be equipped with a conventional auxiliary balance box 68 (Figure 21) by conventional means, and a conventional lifting or lifting device can be used to adjust the auxiliary balance. The position of the box is then fixed. The back-hanging structure (Figure 3) is a variant of the frame structure, which is used when there is no need to set up a box. The free-hinged structure is shown in Figures 4-13. The production requirements are high. From the end of the donkey's head, the balance box / block must be symmetrical to the left and right. Regardless of the structure, the lower part of the balance box / block can also be connected with multiple auxiliary lower boxes / blocks, and the top surface of the lowermost balance box / block is provided with a gasket 67 with a thickness of not less than 5-10 mm. The lower case is unloaded on the flushing device, and the gasket is removed. The pumping unit can operate normally without colliding with the top of the removed box. The removed gasket can be reset and the auxiliary lower case can be reattached to the balancing device. . This structure will help reduce the load on the motor during the initial installation and will be beneficial to operations such as "touching the pump".
本发明抽油机的支架, 可采用塔式双层支架结构, 也可采用常规结构。 本发明抽油机的曲柄, 可 采用直曲柄, 也可采用三角曲柄, 图 22 是三角曲柄的结构示意图, 特征在于: 联接诸曲柄销孔中心 的直线与曲柄主轴孔中心联为一个三角形。 The bracket of the pumping unit of the present invention may adopt a tower double-layer bracket structure or a conventional structure. The crank of the pumping unit of the present invention may adopt a straight crank or a triangular crank. FIG. 22 is a schematic structural diagram of a triangular crank, which is characterized in that a straight line connecting the centers of the crank pin holes and the center of the crank spindle hole is connected into a triangle.
本发明规定质心下置平衡游梁抽油机实施例均是前置式结构, 也可采用后置式, 只要将连杆 6同 游梁 8的铰接点设置在弯游梁后部, 就得到后置式的规定质心下置平衡游梁抽油机了。 本发明规定质 心下置平衡装置, 可单独使用, 也可与常规平衡方式混合使用, 因此, 本发明还可用来对现有常规游 梁抽油机进行节能改造, 只要是游梁抽油机, 都可采用本发明的规定质心下置平衡装置。 According to the present invention, the embodiments of the centrifugal beam pumping unit under the center of gravity are all of the front structure, and the rear structure can also be adopted. As long as the hinge point of the connecting rod 6 and the beam 8 is set at the rear of the curved beam, the rear can be obtained. The center-mounted balanced beam pumping unit is installed under the specified center of mass. The present invention provides that the center-of-mass balance device can be used alone or mixed with the conventional balance method. Therefore, the present invention can also be used for energy-saving reconstruction of existing conventional beam pumping units, as long as it is a beam pumping unit, Both can be used in accordance with the provisions of the invention under the center of mass balance device.
本发明抽油机与海内外游梁抽油机相比, 在各个方面均属领先地位: 1 , 曲柄峰值扭矩降低幅度 达 30~60%: 节电率幅度达 30~50%。 2, 整机结构简单可靠。 3, 安装维护和调参方便。 4, 调平衡方便, 平衡率可达 98%。 5, 整机重量轻, 降低幅度达 30%。 6, 制造成本降低 20%。 7, 整机受力状况改善, 易损件减少, 机器寿命延长。 Compared with domestic and overseas beam pumping units, the pumping unit of the present invention is in a leading position in all aspects: 1. The peak torque of the crankshaft is reduced by 30 to 60%; the power saving rate is 30 to 50%. 2. The structure of the whole machine is simple and reliable. 3. Easy installation and maintenance. 4, easy to adjust the balance, the balance rate can reach 98%. 5. The whole machine is light in weight, with a reduction of 30%. 6, Reduce manufacturing costs by 20%. 7. The mechanical condition of the machine is improved, the wearing parts are reduced, and the machine life is prolonged.
下面证明: 本发明抽油机的 "规定质心下置平衡"是一种最佳平衡方式。 The following proves that the "prescribed centroid-centered balance" of the pumping unit of the present invention is an optimal balancing method.
(一) 摆锤平衡可直接并完全平衡游梁系统的惯性力矩 (I) Pendulum balance can directly and completely balance the moment of inertia of the beam system
设想一种摆锤平衡, 如图 23之 mc, 它置于游梁摆动中心 0的下方, 并且质心位于过 0点所作 游梁的下垂线上, 如同一个与游梁联为一体的摆锤, 摆长为 0 点至 mc质心的距离 H。 容易证明: 摆 锤 mc产生的重力矩 Mc可直接并完全平衡游梁系统的惯性力矩 Mn。 Imagine a balanced pendulum, of FIG. M c 23, which is placed below the center of the swing beam 0, and through the center of mass made 0:00 sagging line beam, as a beam associated with one of the pendulum as , The pendulum length is the distance H from 0 point to the center of mass of m c . It is easy to prove: The mass moment Mc generated by the pendulum mc can directly and completely balance the moment of inertia Mn of the beam system.
设曲柄 R以角速度 ω逆钟向匀速旋转, 其角位移 Θ和游梁(即摇杆 S )角位移 Φ均逆钟向为正。 由投影关系: Suppose that the crank R rotates at a constant speed against the clock direction at an angular velocity ω, and its angular displacement Θ and the angular displacement Φ of the beam (ie, the rocker S) are positive against the clock direction. Relationship by projection:
T= - R cos θ +p cos δ - S sin * (1) T =-R cos θ + p cos δ-S sin * (1)
因连杆 P之摆角 δ很小, cos S l ; 又 φ 30° 时, Φ与 sin *之差不超过 4. 72%, 如令 T=P, 并略去 微量, 由式(1)可得: Because the swing angle δ of the connecting rod P is small, cos S l; At φ 30 °, the difference between Φ and sin * does not exceed 4. 72%, if let T = P, and omit the trace, from formula (1) Available:
Φ = sin t = ― (R/S ) cos Θ
Φ' = άΦ/άθ= (R/S) sin θ (2) Φ = sin t = ― (R / S) cos Θ Φ '= άΦ / άθ = (R / S) sin θ (2)
Φ"= d24>/ d92= (R/S) cos θ Φ "= d 2 4> / d9 2 = (R / S) cos θ
抽油机的惯性力矩将由游梁系统的 Q、 mc和游梁 (平衡) 质量 m (力臂 L) 以及游梁转动惯量 J产生, 它们对游梁摆动中心 0之力矩为: The inertia moment of the pumping unit will be generated by Q, mc of the beam system and the mass m (force arm L) of the beam and the moment of inertia J of the beam. Their moments to the swing center 0 of the beam are:
Mn = (Li2 Q + L2 m +H2 mc ) · (R/S) ω2 · cos Θ (3) Mn = (Li 2 Q + L 2 m + H 2 mc) · (R / S) ω 2 · cos Θ (3)
摆锤 mc对游梁摆动中心之重力矩为:The weight moment of the pendulum m c to the swing center of the beam is:
G = H Hlc g · είηΦ = - H mc g · (R/S) cos Θ (4) G = H Hlc g · είηΦ =-H mc g · (R / S) cos Θ (4)
Mc— 0与 Mn— Θ是两条反相的余弦曲线, 只要幅度相等, 即有 Mn
摆锤可在内部直接平衡游梁 系统的惯性力矩; 此时, H必须符合方程 Mc— 0 and Mn— Θ are two inverse cosine curves. As long as the amplitudes are equal, there is Mn. The pendulum can directly balance the moment of inertia of the beam system; at this time, H must meet the equation
H2- (g/。2) · H + (LrQ/mc + L mc + J/mc) =0 (5) H 2- (g /. 2 ) · H + (LrQ / mc + L mc + J / mc) = 0 (5)
解出 solve
H =0.5{ g/(J2-[ g2/"4- 4(ϋ /Π^ + LWmc + J/mc)]05} (6) H = 0.5 {g / (J 2 - [g 2 / "4 - 4 (ϋ / Π ^ + LWmc + J / mc)] 05} (6)
H必须是实数, 条件是 H must be a real number, provided that
ω [o.25gV ( Li2Q/mc + L2m/mc + j/mc)] 025 (7) ω [o.25gV (Li 2 Q / mc + L 2 m / mc + j / mc)] 025 (7)
由条件 (7)限定的抽油机冲次 n,从 6米长冲程的 n 8冲, 到 1米短冲程的 n 20冲, 足可满足实际需 要。 The number of strokes n of the pumping unit defined by condition (7), from 8 strokes of 6 meters long stroke to n 20 strokes of 1 meter short stroke, is sufficient to meet actual needs.
摆缍平衡和任何常规平衡方式结合, 都可在游梁内部完全平衡游梁系统的惯性力, 获得最佳平衡 效果。 The combination of pendulum balance and any conventional balance method can fully balance the inertia force of the beam system within the beam, and obtain the best balance effect.
(二)游梁下置平衡 =游梁平衡 +摆 衡 (2) Lower beam balance = beam balance + pendulum balance
摆锤平衡和游梁平衡结合, 可产生一种新的平衡一平衡质量的质心置于游梁后部下方, 并且在 抽油机运转中, 平衡质量的质心或作用质心与游梁无相对运动, 如同一个刚体。这种新的平衡称为"规 定质心下置平衡"(简称下置平衡)。 已有技术中也有将平衡质量置于游梁后下方的平衡方式, 但它们 的质心 /作用质心或随着抽油机的运转对于游梁作有规律的相对运动, 或者它们的质心 /作用质心位于 游梁中心线上而不在游梁下方, 因此, 这里所说的 "下置平衡"与它们有着实质的区别。 The combination of the balance of the pendulum and the balance of the beam can generate a new kind of balance. The center of mass of the balanced mass is placed below the rear of the beam. During the operation of the pumping unit, the center of mass or the center of mass of the balanced mass has no relative movement with the beam. Like a rigid body. This new balance is called the "regular centroid under balance" (referred to as the under balance). In the prior art, there are also balancing methods that place the balance mass behind and behind the beam, but their center of mass / acting center of mass or regular relative movement to the beam as the pumping unit operates, or their center of mass / acting center of mass It is located on the center line of the beam and not below the beam. Therefore, the "under balance" mentioned here is substantially different from them.
这里所说的 "下置平衡"是一种奇妙的平衡, 奇妙之处在于一个下置质量可当两个质量用: 一 个在游梁尾端, 另一个在游梁的中垂线上, 因此, 是一种全新的两级平衡。 图 25 是一种游梁复合平 衡抽油机简图: 置于游梁尾端 B处的质量 me是传统的游梁平衡, 置于游梁过摆动中心 0的下垂线上 C 处的质量 mc是如同一个单摆的摆锤平衡, 容易证明, 只要 0BGC是矩形以及 = mc = m, 置于 G处的 游梁下置质量 m (图 24) 与游梁复合平衡 (图 25)动态等价。 The "under balance" mentioned here is a wonderful balance. The strange thing is that one under mass can be used as two masses: one at the end of the beam and the other at the mid-vertical line of the beam. Is a new two-level balance. Figure 25 is a simplified diagram of a beam balance pumping unit: The mass me placed at the tail end B of the beam is the traditional beam balance, and the mass m placed at C on the droop line of the beam past the swing center 0 c is a pendulum balance like a single pendulum. It is easy to prove that as long as 0BGC is rectangular and = m c = m, the mass m below the beam at G (Figure 24) is balanced with the beam (Figure 25). Equivalent.
图 24, 游梁 8上质心位于 G的质量 m, 在运动中对游梁摆动中心 0产生的力矩 Mc由两部分构 成, 一部分是 m的重力对 0的力矩, 等于矢经 0G与重力矢量 mgi的矢积 OGXmgi (i为指向地心的 单位矢量); 另一部分是游梁摆动时 m的惯性力对 0的力矩, 等于矢径 0G与 m的切向惯性力 Πΐρετ的 矢积 OGXmpst (ε是游梁 8的角加速度, τ、 T τ2分别是垂直于 0G、 0B、 0C的单位切向矢量), 因此:Figure 24. The mass m of the center of mass on the walking beam 8 is located at G. The moment Mc generated by the swing center 0 of the walking beam in motion is composed of two parts. One part is the moment of gravity of m against 0, which is equal to the sagittal 0G and the gravity vector mg. The vector product of i is OGXmgi (i is the unit vector pointing to the center of the earth); the other part is the moment of inertia force of m against 0 when the beam is swinging, which is equal to the vector product of the tangential inertial force of the vector diameter 0G and m Πΐρετ (ε Is the angular acceleration of the beam 8 and τ, T τ 2 are unit tangential vectors perpendicular to 0G, 0B, 0C, respectively), so:
MG = (0BXmgi+ OBXmLsTi) + (0CXmgi+ 0CXmHsT2) MG = (0BXmgi + OBXmLsTi) + (0CXmgi + 0CXmHsT2)
显然, (OBXragi+OBXmLsTi) = MB与 (0CXmgi+ 0CXmHeT2) = c, 分别是图 25中游梁 8上质心位于Obviously, (OBXragi + OBXmLsTi) = MB and (0CXmgi + 0CXmH e T 2 ) = c, respectively, the center of mass on the beam 8 in Figure 25 is located at
B, C的质量 me=m和 mc=m的重力和惯性力对游梁摆动中心 0的力矩, 这就是说, MG= B+MC。 The moments of the masses B, C of me = m and m c = m, the moment of gravity and inertia force on the swing center 0 of the beam, that is, M G = B + MC.
结论: "游梁下置平衡"与 "游梁平衡和摆锤平衡的复合平衡", 两者动态等价; 或者说: "游梁 下置平衡可动态等价地分解为游梁分量平衡和摆锤分量平衡"。 Conclusion: "Beam under beam balance" and "Composite balance of beam balance and pendulum balance" are dynamically equivalent; or "Beam under balance can be dynamically and equally decomposed into beam component balance and Pendulum component balance ".
(三)下置平衡的实质一 -储存位能和动能 (Three) the essence of the underlying balance-stored potential energy and kinetic energy
游梁下置平衡的游梁分量和摆锤分量, 分别用来平衡抽油机悬点重力负荷和游梁系统的惯性 力。 这两种平衡实质上都是抽油机内在机械能的转移和储存: The balance beam component and pendulum component under the balance beam are used to balance the gravity load of the pumping unit suspension point and the inertia force of the balance beam system, respectively. Both of these balances are essentially the transfer and storage of mechanical energy inherent in pumping units:
游梁分量用来储存悬点悬挂质量 Q的重力位能: 曲柄从上死点 ( Q π ) 到下死点 ( Θ 0), Q之位能丢失达最大值 G, 游梁分量之位能增加达最大值 G1; 曲柄从下死点到上死点, 刚好反过来。 这样, G→ Gi→ G→ G,……反复循环, Q之位能得以转移储存, 不致丢失, 达到节能的目的。 位能完 全储存的条件是 = G, g : The beam component is used to store the gravitational potential energy of the suspension mass Q: The crank can be lost from the top dead point (Q π) to the bottom dead point (Θ 0). Increase up to the maximum G 1; the crank goes from bottom dead center to top dead center, just the other way round. In this way, G → Gi → G → G, ... repeatedly cycle, the position of Q can be transferred and stored without loss, thus achieving the purpose of energy saving. The condition that the bit can be completely stored is = G, g :
摆锤分量用来转移和储存游梁系统之动能: 上、 下死点 ( θ ^π、 0) 时游梁系统动能为 0, 摆锤分量重力位能达最大值 G2; 游梁水平位置 ( θ =90° , 270° ) 时, 游梁系统动能达最大值 E, 摆 缍分量重力位能为 0, 由 E→ G2→E→ G2……, 使游梁系统之动能转移为摆锤之位能而不致流失。 理 想状态应有 E=G, 引入式 (2) 可推得 The pendulum component is used to transfer and store the kinetic energy of the beam system: The kinetic energy of the beam system is 0 at the upper and lower dead points (θ ^ π , 0), and the gravity position of the pendulum component can reach the maximum value G 2; the horizontal position of the beam (Θ = 90 °, 270 °), the kinetic energy of the traveling beam system reaches the maximum value E, the gravitational potential energy of the pendulum component is 0, and the kinetic energy of the traveling beam system is transferred to the pendulum from E → G2 → E → G2 …… The place can not be lost. The ideal state should have E = G, which can be inferred from the introduction formula (2)
H2- (Ε/ω2) ·Η + (L2 +LLi + J/m) =0 (9) 式 (9) 与式 (5) 是一致的, 在式 (5) 中代入 mc=m和 mL-QLi,就可得到式 (9), 这再次证明 "动能 储存理论"之正确。 H 2- (Ε / ω 2 ) · Η + (L 2 + LLi + J / m) = 0 (9) Formula (9) is consistent with formula (5), substitute mc = m in formula (5) And mL-QLi, we can get formula (9), which proves the correctness of the "kinetic energy storage theory" again.
抽油机悬点负荷主要包括抽油机重量 C 和所提升油柱重量 Q2, 以及 Q Q2的惯性力, 其次是 种种因素 (主要是摩擦力、 振动等因素) 产生的阻止抽油杆运动的阻力 F。 阻力作功总是转变为热量 而流失, 是不可能用机械方法转移、 储存的。 常规曲柄平衡和游梁平衡, 能使 C 、 Q2之位能转移储存, 但不能使它们的动能转移、 储存。 毫无疑问, 能使 Q2之位能和动能在上、 下冲程均能全部转移、 储存而不致流失的平衡将是节能效果达到理想境界的最佳平衡, 规定质心下置平衡就是这种最佳平 衡。 图 26、 27可资佐证: 图 26为同等负荷下型式试验时之曲柄扭矩曲线, 图 27为同等井况同等冲 程下抽油作业时在最佳平衡状态下的曲柄扭矩曲线界限, 图中, ①一规定质心下置平衡, 冲次为各设 计冲次; (1一常规游梁平衡, 冲次接近于零; ③常规游梁平衡, 最高设计冲次; ④一与③相应的惯性 力矩。 ①与②相近且与冲次无关说明规定质心下置平衡完全平衡了惯性力矩, ③之峰值远大于②并且 ③ ^② +④, 说明常规游梁平衡完全没有平衡惯性力矩。 与常规或异相曲柄平衡方式比较, 可有相仿 的结果。
Suspension point load of the pumping unit mainly includes the weight of the pumping unit C and the weight of the lifted oil column Q 2 , and the inertia force of QQ 2 , followed by various factors (mainly friction, vibration and other factors) that prevent the movement of the sucker rod. The resistance F. Resistance work is always converted into heat and lost, and it is impossible to transfer and store it mechanically. The conventional crank balance and beam balance can transfer and store the C and Q 2 positions , but they cannot transfer and store their kinetic energy. Undoubtedly, the balance that allows Q 2 ’s position energy and kinetic energy to be fully transferred in both the up and down strokes and stored without loss will be the best balance for energy saving effects to reach the ideal state. The regulation of the center of mass under the balance is the best Good balance. Figures 26 and 27 can be proved: Figure 26 is the crank torque curve during the type test under the same load, and Figure 27 is the limit of the crank torque curve under the optimal balance state during the pumping operation under the same well condition and the same stroke. ① A specified center-of-mass balance, and the strokes are the design strokes; (1—the conventional beam balance, the stroke is close to zero; ③ the conventional beam balance, the highest design stroke; ④—the corresponding inertia moment of ③. ① is close to ② and has nothing to do with the impulse, indicating that the inertia moment is completely balanced under the center of mass balance, and the peak value of ③ is much larger than ② and ③ ^ ② + ④, indicating that the conventional beam balance has no equilibrium inertia moment. Comparison of crank balance methods can have similar results.
Claims
1. 一种规定质心下!:平衡游梁抽油机, 包括动力机: 带传动装置; 减速机; 曲柄; 连杆; 横梁及横梁 轴承座; 整体或组合弯游梁; 游梁支承; 片状或轮状驴头及挂在驴头上的悬绳器: 刹车装 a: 支架; 底盘和承冲装置; 常规平衡装置; 以及联接在弯游梁尾端的游梁下置平衡装置, 其特征在于: 所述 游梁下置平衡装置是一种铰,挂在弯游梁尾端的具有规定质心结构的下置平衡箱 /块。 1. Under a prescribed centroid! : Balance beam pumping unit, including power machine: belt drive; reducer; crank; connecting rod; beam and beam bearing seat; integral or combined curved beam; beam support; sheet or wheel donkey head and hanging on Suspension device on donkey head: brake device a: bracket; chassis and impact bearing device; conventional balance device; and lower beam balance device connected at the tail end of curved beam, which is characterized in that: the beam is balanced below The device is a hinge, a lower balance box / block with a specified center of mass structure hanging at the end of a curved beam.
2. 根据权利耍求 1 的规定质心下置平衡游梁抽油机, 特征在于规定质心结构包括调变质心结构和测定 质心结构: 调变质心结构是一种框架结构楼式平衡箱——用三至四根等长立柱焊接上、 下底板构成 一个框架, 该框架上 /下部单独或同时联接有上厂 F平衡箱, 构成具有两个对称面的独立整体, 一个 对称面与抽油机对称面重合, 另一个对称面与游梁作用线垂直: 测定质心结构是楼式平衡箱具有的 挂轴 /挂钩 ·标尺结构和包容结构——挂轴 /挂钩 ·标尺结构是: 楼式平衡箱的前、 后侧面上装有至少 一个挂轴 /挂钩, 弯游梁尾端装有挂座 /挂钩或挂轴, 并且楼式平衡箱的左 /右侧面中线处设有自游 梁作用线起算的标尺 27; 包容结构是: 楼式平衡箱前侧面的两根立柱在整机对称面垂直方向的间 距大于弯游梁尾端的宽度, 楼式平衡箱通过靠闩 24与弯游梁尾端相靠。 2. According to the requirements of claim 1, the center-of-center balanced beam pumping unit is characterized in that the specified center-of-mass structure includes a modulated center-of-mass structure and a measurement of the center-of-center structure: Three to four equal-length columns are welded with upper and lower base plates to form a frame. The upper / lower frame of the frame is separately or simultaneously connected with the upper factory F balance box to form an independent whole with two symmetrical planes. One symmetrical plane is symmetrical to the pumping unit. The surfaces are coincident, and the other symmetry plane is perpendicular to the action line of the beam: The centroid structure is determined by the hanging shaft / hook · ruler structure and containment structure of the building balance box—the hanging shaft / hook · ruler structure is: At least one hanging shaft / hook is installed on the front and rear sides, a hanging seat / hook or hanging shaft is installed at the end of the curved beam, and the left / right side of the floor balance box is provided with a line from the beam's action line. Ruler 27; The containment structure is: The distance between the two columns on the front side of the floor balance box in the vertical direction of the plane of symmetry of the whole machine is greater than the width of the end of the bending beam. The floor balance box is The beam ends lean against each other.
3. 根据权利要求 1 的规定质心下 E平衡游梁抽油机, 特征在于: 规定质心结构是一种多挂轴 /挂钩平 衡箱: 平衡箱制成独立的矩形结构, 或矩形平衡箱上部联有两根立柱上加横杆延伸出一个挂背, 或 用四根立柱上加顶板延伸出一个框架结构, 平衡箱或其延伸部分错距装有至少三个挂轴 /挂钩; 弯 游梁尾部则装有挂座、 挂钩或挂轴, 平衡箱的挂轴 /挂钩铰挂在弯游梁尾部的挂座、 挂钩 /挂轴上, 并通过靠闩与弯游梁尾端相靠。 3. The E-balance beam pumping unit under the specified center of mass according to claim 1, characterized in that: the specified center of mass structure is a multi-hanging shaft / hook balance box: the balance box is made of a separate rectangular structure, or the upper part of the rectangular balance box is connected There are two uprights with crossbars to extend a hanging back, or four uprights with a top plate to extend a frame structure. The balance box or its extension is equipped with at least three hanging shafts / hooks at staggered distances; Then, a hanging seat, a hook or a hanging shaft is installed, and a hanging shaft / hook of the balance box is hinged on the hanging seat, a hook / hanging shaft at the rear of the bending beam, and is abutted against the tail end of the bending beam by a latch.
4. 根据权利要求 1 的规定质心下置平衡游梁抽油机, 特征在于: 规定质心结构是一种调位块 ·平衡箱 / 块铰挂系统——联接在弯游梁尾端或与弯游梁尾端联为一体的调位块上制有至少三个园孔: 钩状或 迷宫式 U形孔、 方孔或钩状方孔, 或制有至少一个长槽, 平衡箝 /块通过与之联接的吊板 /吊杆或吊 钩, 自由铰挂在所说孔、 槽中。 4. The lower center-center balanced beam pumping unit according to claim 1, characterized in that: the specified center-of-centre structure is a positioning block, balance box / block hinge system-connected at the tail end of the curved beam or with the bend At least three circular holes are made on the adjustment block with the end of the beam as a whole: hook-shaped or labyrinth-shaped U-shaped holes, square holes or hook-shaped square holes, or at least one long groove, and the balance clamp / block passes through The hanging plate / hook or hook connected to it is freely hung in said hole or slot.
5. 根据权利要求 1 的规定质心下置平衡游梁抽油机, 特征在于: 规定质心结构是一种吊钩 ·平衡箱 /块 铰挂系统——弯游梁尾端或联接在弯游梁尾端的调位块上, 铰接有至少三个吊钩, 平衡箱 /块通过 吊板 /吊杆, 自由铰挂在所说吊钩上。 5. The lower center-center balanced beam pumping unit according to claim 1, characterized in that: the specified center-of-mass structure is a hook-balance box / block hinge system-the tail end of the swing beam or connected to the swing beam At the end of the adjustment block, at least three hooks are articulated, and the balance box / block is freely hung on the hook through the hanging plate / hanger.
6. 根据权利要求 1 的规定质心下 ffi平衡游梁抽油机, 特征在于: 规定质心结构采用了三角桁架》平衡 箱 /块铰挂系统——有两根伸缩杆, 它们的上端分别铰接在游梁上, 下端则相互铰接, 构成一个可 调变的三角桁架式的弯游梁; 平衡箱 /块直接或通过吊 /挂钩自由铰挂在三角珩架的下部铰接点处。 6. The ffi balanced beam pumping unit under the specified center of mass according to claim 1, characterized in that: the specified center of mass structure uses a triangular truss "balance box / block hinge system-there are two telescopic rods, and their upper ends are hinged at The upper and lower ends of the beam are articulated to each other to form an adjustable triangular truss-type curved beam; the balance box / block is freely hinged directly or through a suspension / hook at the lower hinge point of the triangle frame.
7. 根据权利耍求 1的规定质心下 S平衡游梁抽油机, 特征在于: 组合弯游梁中平衡臂 8. 1与游梁 8尾 端之联接, 以及平衡箱 62 平衡臂 8. 1尾端之联接, 采用相同的挂 *靠结构: 上部铰挂, 下部通过 一种角度调节装 S相靠, 角度调节装 S由安装架 60 与安放在安装架中的角度调节元件构成, 调节 元件可采用角度调节片, 还可采用角度调节块、 销轴以及千斤顶。 7. The S-balance beam pumping unit under the center of mass according to claim 1, characterized in that: the combination of the balance arm 8.1 in the curved beam and the tail end of the beam 8 and the balance box 62 balance arm 8.1 The connection at the tail end adopts the same hanging and leaning structure: the upper part is hung, and the lower part is leaned by an angle adjusting device S. The angle adjusting device S is composed of a mounting bracket 60 and an angle adjusting element placed in the mounting bracket. The adjusting element The angle adjustment piece can be used, and the angle adjustment block, pin and jack can also be used.
8. 根据权利耍求 1 的规定质心下 :平衡游梁抽油机, 特征在于: 平衡箱 /块下部还可用螺栓联接多个 平衡箱 /块, 并且最底部平衡箱 /块的顶面上设置有厚度不小 T- 5-10毫米的垫片 67。 8. According to the requirement of claim 1, under the centroid of balance: a balanced beam pumping unit, characterized in that the lower part of the balance box / block can also be connected with multiple balance boxes / blocks by bolts, and the top surface of the bottommost balance box / block is set There are washers 67 with a thickness of not less than T-5-10mm.
9. 根据权利要求 1的规定质心下 S平衡游梁抽油机, 特征在于: 采用了塔式双层支架结构: 下支架 55 与底盘联结为一个整体, 上支架设计成整体钢结构或装配式三角撑, 用螺栓联接在下支架上。 9. The S-balanced beam pumping unit under the center of mass according to claim 1, characterized by: adopting a tower double-layer bracket structure: the lower bracket 55 is connected to the chassis as a whole, and the upper bracket is designed as an integral steel structure or assembling Tripods are bolted to the lower bracket.
10. 根据权利耍求 1 的规定质心下置平衡游梁抽油机, 特征在丁- : 曲柄上诸销孔的中心连线, 与曲柄 主轴孔之中心构成一个三角形。 10. According to the requirements of claim 1, the center-of-center balanced beam pumping unit is characterized in that the center of the pin holes on the D-: crank is connected with the center of the crank main hole to form a triangle.
0
0
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN00101331 | 2000-01-06 | ||
CN00101331.9 | 2000-01-06 |
Publications (1)
Publication Number | Publication Date |
---|---|
WO2001055552A1 true WO2001055552A1 (en) | 2001-08-02 |
Family
ID=4575885
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/CN2001/000005 WO2001055552A1 (en) | 2000-01-06 | 2001-01-03 | An oil pumping unit with a counterweight whose centroid can be adjusted |
Country Status (1)
Country | Link |
---|---|
WO (1) | WO2001055552A1 (en) |
Cited By (13)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US7799968B2 (en) | 2001-12-21 | 2010-09-21 | Kimberly-Clark Worldwide, Inc. | Sponge-like pad comprising paper layers and method of manufacture |
US7994079B2 (en) | 2002-12-17 | 2011-08-09 | Kimberly-Clark Worldwide, Inc. | Meltblown scrubbing product |
CN104912521A (en) * | 2015-04-15 | 2015-09-16 | 吕传庆 | Novel pumping unit convenient to integrally seal |
CN105840145A (en) * | 2015-01-13 | 2016-08-10 | 中国石油天然气股份有限公司 | Switched reluctance motor direct-drive oil production device |
CN105986783A (en) * | 2015-02-09 | 2016-10-05 | 中国石油天然气股份有限公司 | Oil pumping unit |
DE102010023630B4 (en) * | 2010-06-14 | 2017-11-02 | Sew-Eurodrive Gmbh & Co Kg | Conveying device with connecting rod and method for controlling a conveyor device with connecting rod and at least one balance weight |
EP2603763A4 (en) * | 2010-08-09 | 2018-01-24 | Lufkin Industries, LLC | Beam pumping unit for inclined wellhead |
CN109339744A (en) * | 2018-10-26 | 2019-02-15 | 中国石油化工股份有限公司 | It is a kind of to automatically adjust balancing device and method without driving beam pumping unit |
CN110029966A (en) * | 2018-01-11 | 2019-07-19 | 中国石油天然气股份有限公司 | Balance adjusting device and oil pumping unit |
WO2019241864A1 (en) * | 2018-06-20 | 2019-12-26 | Petróleo Brasileiro S.A. - Petrobras | Land-based pumping unit |
CN110863802A (en) * | 2019-12-26 | 2020-03-06 | 祁晨龙 | Beam-pumping unit support arm structure and using method thereof |
CN111720099A (en) * | 2020-07-20 | 2020-09-29 | 成都鑫泽机械有限公司 | Beam pumping unit beam structure convenient to install and installation and maintenance method |
CN113338863A (en) * | 2020-02-18 | 2021-09-03 | 中国石油天然气股份有限公司 | Pumping-stop-free collision pump device for pumping unit well |
Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1039868A (en) * | 1988-10-30 | 1990-02-21 | 汪朴澄 | Two-stage balance bar beam-punping unit |
CN2168096Y (en) * | 1993-04-26 | 1994-06-08 | 汪朴澄 | Pumping unit |
CN1088665A (en) * | 1992-12-21 | 1994-06-29 | 汪朴澄 | High-efficient energy-saving lever oil pumping machine |
CN2206360Y (en) * | 1994-09-29 | 1995-08-30 | 萧炘 | Material-saving energy-saving oil pumping unit |
CN2289075Y (en) * | 1996-01-09 | 1998-08-26 | 汪朴澄 | Balanced arm type two-stage beam-balanced pump |
US5827051A (en) * | 1995-12-13 | 1998-10-27 | Air-Go Windmill, Inc. | Regenerative hydraulic power transmission for down-hole pump |
CN2312323Y (en) * | 1997-12-31 | 1999-03-31 | 新疆维吾尔自治区第三机床厂 | Walking-beam balancing, diameter-adjusting and torque-changing energy saving oil pumping machine |
-
2001
- 2001-01-03 WO PCT/CN2001/000005 patent/WO2001055552A1/en active Application Filing
Patent Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1039868A (en) * | 1988-10-30 | 1990-02-21 | 汪朴澄 | Two-stage balance bar beam-punping unit |
CN1088665A (en) * | 1992-12-21 | 1994-06-29 | 汪朴澄 | High-efficient energy-saving lever oil pumping machine |
CN2168096Y (en) * | 1993-04-26 | 1994-06-08 | 汪朴澄 | Pumping unit |
CN2206360Y (en) * | 1994-09-29 | 1995-08-30 | 萧炘 | Material-saving energy-saving oil pumping unit |
US5827051A (en) * | 1995-12-13 | 1998-10-27 | Air-Go Windmill, Inc. | Regenerative hydraulic power transmission for down-hole pump |
CN2289075Y (en) * | 1996-01-09 | 1998-08-26 | 汪朴澄 | Balanced arm type two-stage beam-balanced pump |
CN2312323Y (en) * | 1997-12-31 | 1999-03-31 | 新疆维吾尔自治区第三机床厂 | Walking-beam balancing, diameter-adjusting and torque-changing energy saving oil pumping machine |
Cited By (16)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US7799968B2 (en) | 2001-12-21 | 2010-09-21 | Kimberly-Clark Worldwide, Inc. | Sponge-like pad comprising paper layers and method of manufacture |
US7994079B2 (en) | 2002-12-17 | 2011-08-09 | Kimberly-Clark Worldwide, Inc. | Meltblown scrubbing product |
DE102010023630B4 (en) * | 2010-06-14 | 2017-11-02 | Sew-Eurodrive Gmbh & Co Kg | Conveying device with connecting rod and method for controlling a conveyor device with connecting rod and at least one balance weight |
US10605240B2 (en) | 2010-06-14 | 2020-03-31 | Sew-Eurodrive Gmbh & Co. Kg | Delivery device having a connecting rod, and a method for controlling a delivery device having a connecting rod and at least one balance weight |
EP2603763A4 (en) * | 2010-08-09 | 2018-01-24 | Lufkin Industries, LLC | Beam pumping unit for inclined wellhead |
CN105840145A (en) * | 2015-01-13 | 2016-08-10 | 中国石油天然气股份有限公司 | Switched reluctance motor direct-drive oil production device |
CN105986783A (en) * | 2015-02-09 | 2016-10-05 | 中国石油天然气股份有限公司 | Oil pumping unit |
CN104912521A (en) * | 2015-04-15 | 2015-09-16 | 吕传庆 | Novel pumping unit convenient to integrally seal |
CN110029966A (en) * | 2018-01-11 | 2019-07-19 | 中国石油天然气股份有限公司 | Balance adjusting device and oil pumping unit |
WO2019241864A1 (en) * | 2018-06-20 | 2019-12-26 | Petróleo Brasileiro S.A. - Petrobras | Land-based pumping unit |
CN109339744A (en) * | 2018-10-26 | 2019-02-15 | 中国石油化工股份有限公司 | It is a kind of to automatically adjust balancing device and method without driving beam pumping unit |
CN109339744B (en) * | 2018-10-26 | 2023-08-15 | 中国石油化工股份有限公司 | Automatic balance adjusting device and method for non-driving beam pumping unit |
CN110863802A (en) * | 2019-12-26 | 2020-03-06 | 祁晨龙 | Beam-pumping unit support arm structure and using method thereof |
CN113338863A (en) * | 2020-02-18 | 2021-09-03 | 中国石油天然气股份有限公司 | Pumping-stop-free collision pump device for pumping unit well |
CN113338863B (en) * | 2020-02-18 | 2022-07-05 | 中国石油天然气股份有限公司 | Pumping-stop-free collision pump device for pumping unit well |
CN111720099A (en) * | 2020-07-20 | 2020-09-29 | 成都鑫泽机械有限公司 | Beam pumping unit beam structure convenient to install and installation and maintenance method |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
WO2001055552A1 (en) | An oil pumping unit with a counterweight whose centroid can be adjusted | |
CN108952137A (en) | A kind of civil engineering construction construction load-bearing hanger being easily installed | |
CN106198073A (en) | The multi-functional testing agency of polytype door and window and accessory performance thereof can be detected simultaneously | |
CN207760855U (en) | A kind of highway structure construction ringing engine | |
CN107905120A (en) | A kind of bridge construction vibreatory hammer | |
CN108824202B (en) | Support system for concrete cable-stayed bridge hanging basket installation and tower area beam cast-in-situ construction | |
CN212581369U (en) | Balance hanger for PC component | |
CN110821447B (en) | Energy-saving beam pumping unit with good stability | |
CN201381840Y (en) | Large-size long-stroke heavy-load energy-saving oil pumping unit | |
Ahmedov et al. | Estimation of the equality of the beamless sucker-rod oil pumping unit by the value of the consumption current | |
CN208932801U (en) | Tower crane stake bracing means | |
CN103267691A (en) | Damp-adjustable dual-oscillating-bar impact testing machine | |
CN201339466Y (en) | Double-horsehead balance adjusting type energy-saving oil pumping unit | |
CN109667563A (en) | A kind of energy-saving pumping unit | |
CN201953356U (en) | Oil pumping machine | |
CN209586338U (en) | A kind of energy-saving pumping unit | |
CN211693986U (en) | Anti-seismic support and hanger based on disk spring vibration reduction | |
CN112112605B (en) | Energy-saving intelligent beam pumping unit | |
CN211478364U (en) | Flow measuring device for hydraulic engineering | |
CN111576893B (en) | Mounting device for stair railing fixing screw rod | |
US2179649A (en) | Beam weight | |
CN110529078B (en) | Oil pumping unit | |
CN102155189A (en) | Balancing torque converting device for beam-pumping unit | |
CN2169708Y (en) | Swing rod wheel double well oil pump | |
CN201228540Y (en) | Hanging type beam balancing energy-saving oil pump |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
AK | Designated states |
Kind code of ref document: A1 Designated state(s): GB ID IN JP KR RU US |
|
AL | Designated countries for regional patents |
Kind code of ref document: A1 Designated state(s): AT BE CH CY DE DK ES FI FR GB GR IE IT LU MC NL PT SE TR |
|
121 | Ep: the epo has been informed by wipo that ep was designated in this application | ||
DFPE | Request for preliminary examination filed prior to expiration of 19th month from priority date (pct application filed before 20040101) | ||
122 | Ep: pct application non-entry in european phase | ||
NENP | Non-entry into the national phase |
Ref country code: JP |