CN212317953U - Kowtow type associated gas oil pumping unit - Google Patents
Kowtow type associated gas oil pumping unit Download PDFInfo
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- CN212317953U CN212317953U CN202021778105.7U CN202021778105U CN212317953U CN 212317953 U CN212317953 U CN 212317953U CN 202021778105 U CN202021778105 U CN 202021778105U CN 212317953 U CN212317953 U CN 212317953U
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Abstract
A kowtow type associated gas oil pumping unit replaces the walking beam of an electric kowtow with the swing cylinder of a swing cylinder temperature difference engine thereof; the swing cylinder temperature difference engine directly converts heat energy generated by associated gas combustion into mechanical energy in an external combustion and internal guide mode, replaces a motor of an electric gouging machine, and drives a swing cylinder to swing up and down; the heat energy converter of the engine is a dumbbell-shaped special sealed metal container which is filled with a certain amount of low-boiling-point liquid after being vacuumized. The hot end is provided with an associated gas liquid level heating system; the power generation horsehead is arranged outside the balance system and drives the balance system to work. An oil pumping horsehead is arranged outside the cold head end to drive the oil pumping mechanism to work. The thermodynamic cycle of the engine heat energy conversion belongs to a new thermodynamic cycle mode, has high conversion efficiency, simple equipment and good economical efficiency, can save electricity consumption cost, adopts a low-temperature, low-pressure and low-speed safe and long-life working mode, and can meet the requirement of oil extraction in an oil field.
Description
Technical Field
The invention belongs to the technical field of oil pumping in oil fields, and particularly relates to a device which can swing and pump oil by taking associated gas as heat energy and by using a small temperature difference at two ends of a swing cylinder.
Background
The electric head-knocking oil pumping machine (short for electric head-knocking machine) has a history of one or two hundred years, and is still the main oil extraction equipment of the oil field at present due to simple structure and easy operation, and particularly can work in the oil field for a long time all day. However, because of large electricity consumption, the electricity consumption of the oil well in the middle and later periods accounts for 25% -30% of the oil extraction cost, and becomes a bottleneck for restricting the improvement of the economic benefit of the oil field.
Disclosure of Invention
The invention provides a kowtow associated gas oil pumping unit, aiming at overcoming the problems of large electric quantity and high production cost of the conventional electric kowtow machine. The oil-gas pumping machine does not use electric energy, and uses the oil-associated gas pumped by the oil well as a heat source to drive the knocking head type oil pumping machine to work. The oil field oil extraction device not only can save electricity cost, but also has the advantages that the thermodynamic cycle of the machine heat energy conversion belongs to a new thermodynamic cycle mode, the conversion efficiency is high, the equipment is simple, the economical efficiency is good, and the oil field oil extraction requirement can be met by adopting a low-temperature, low-pressure and low-speed safe and long-life working mode.
The technical scheme adopted by the invention is as follows: replacing an electric kowtow engine walking beam swinging up and down by a swing cylinder of a swing cylinder temperature difference engine in a kowtow associated gas pumping unit; the pendulum cylinder temperature difference engine takes petroleum associated gas as a heat source, directly converts heat energy into mechanical energy, drives the pendulum cylinder to swing up and down, and replaces a motor of an electric head knocking machine; the base support frame supports a swing cylinder heat energy converter of the swing cylinder temperature difference engine, and a certain amount of low-boiling-point liquid is injected into the converter after the converter is vacuumized; the heat head end is provided with an external combustion and internal guide associated gas liquid level heating system; the power generation horsehead is arranged outside the hot head end to drive the balance straight-moving generator to work, and the generated electric energy meets the requirements of various power utilization devices in the kowtow type associated gas oil pumping unit; an oil pumping mule head is arranged outside the cold head end to drive an oil pumping mechanism to work and pump out oil and associated gas; and the safety system of the associated gas storage tank and the control system of the oil pumping unit ensure the safe operation of the head-knocking type associated gas oil pumping unit.
The swing barrel temperature difference engine mainly comprises a swing barrel heat energy converter, an associated gas liquid level heating system (comprising an inner heating device and an outer heating device), a base support frame, a swing barrel clamp holder, a swing bearing, a heat dissipation plate, a sensor, a monitor and the like. The swing cylinder temperature difference engine works under the control of the intelligent controller.
The pendulum cylinder heat energy converter is a dumbbell-shaped special sealed container and is formed by welding a long tubular container and two spherical containers with different spherical diameters. The tube portion is cylindrical or non-cylindrical; the head is hollow spherical or hollow non-spherical. After the sleeve is in place, the sleeve is sealed by welding, as shown in fig. 3. After vacuumizing, a certain amount of low-boiling-point liquid is injected into the container, and gas and liquid cannot overflow. The big bulb is a hot end, the small bulb is a cold end, and the volume of the hot end is larger than that of the cold end.
Firstly, a specially-made sealed container is horizontally placed, a balance axis in the horizontal position is found out in the middle of the length of the tube, horizontal displacement is carried out from the balance axis to the cold head end, and a proper support axis is found out, as shown in figure 2. The support axis must satisfy the following condition: with the axis as the axis, the moment of the hot end (end A) is increased, and the hot end (end A) swings downwards, so that the end A is lowered and the cold end (end B) is raised, and a liquid separation space with gas at both ends A and B is formed.
The heat energy conversion mechanism is as follows: the liquid will generate different saturated vapor pressure at different temperature, and the liquid-gas two-phase change reaches the new balance. Because the liquid level at the hot end of the converter is heated, the enthalpy of the liquid level is increased, the heat increment of the liquid level is small, and the increment of the product of the gas volume and the pressure intensity is large, the small temperature difference of the liquid levels at the two ends of the heat energy converter can generate large saturated vapor pressure difference, the saturated vapor pressure of the liquid level at the hot end of the low-boiling liquid is far higher than that at the cold end, the temperature of the liquid level at the hot end is higher, the temperature of the cold end is unchanged, the pressure difference at the two ends is higher, the liquid in the pipe is forced to flow to the B end, the liquid level at the A end is reduced, the liquid level at the B end is raised, the gravity center moves to; in the process of swinging the end B downwards, as more liquid in the pipe flows to the head part of the end B, the downward moment of the end B is gradually increased, and the swinging is accelerated under the action of the dynamic pressure head; when the swing arm swings to the vicinity of the horizontal position, the gas at the two ends of the pressure sensor A, B is communicated, the gas pressure difference at the two ends is zero, and the dynamic pressure head is also zero. At the moment, the gravity center returns to the end A which is in the horizontal position, the moment of the end A becomes large again, the end A begins to swing downwards again, liquid flows to the end head of the end A and returns to the starting position, the two ends A and B return to the liquid separation space of the original two air chambers, and a movement cycle is completed. When the liquid is pressed to the cold end, the gas space at the cold end is compressed, the vapor pressure of the gaseous medium inside the liquid space is increased to form supersaturated vapor, the corresponding equilibrium temperature of the supersaturated vapor is higher than the equilibrium temperature (environment temperature) of the gas-liquid two phase at the cold end, condensed liquid medium is generated on the inner surface of the shell at the cold end and the liquid surface of the shell, the condensed liquid medium is converged into the liquid medium in the converter, and the released phase change heat is dissipated into the outside air through the shell. This process continues until the thermal energy converter swings to a horizontal position with gas communication between the two ends. Just because the hot end liquid level only increases a small amount of heat (if hot end liquid level medium risees 1 degree centigrade, saturated vapour pressure will have and show to increase) to converter shell adopts high heat conduction metal material, and the internal design has the heating panel, so the small amount of heat of hot end liquid level increase can be in the liquid flow passes through converter shell and transmits to the outside air in, and then guarantees cold junction liquid level temperature stable. Situation when the hot side is heated: the liquid level is heated, the temperature rises, the corresponding equilibrium saturated vapor pressure rises, a condensed liquid medium can be generated on the inner surface of the hot end shell, but the evaporation speed is far higher than the condensation speed; on the other hand, the external heating device is arranged on the upper part of the hot end, the heat conduction pipe is inserted into the shell and connected with the shell, partial heat transferred by the heat conduction pipe can be transferred to the shell on the upper part of the hot end, the output of a condensed liquid medium is reduced, and the liquid in the container is not influenced to be pressed to the cold end. Therefore, under the action of the temperature difference, the heat energy is continuously converted into mechanical energy, and the cycle is repeated and continuous.
The associated gas liquid level heating system adopts a radiation type heating mode of external combustion and internal conduction. The outer heating device is arranged on the upper part outside the hot end and is provided with an associated gas hose, an electronic igniter, a heating disc, a heat conducting pipe and the like. The liquid level of the hot end rises at the starting position, the heating plate is ignited and combusted, the top of the inverted U-shaped heat conduction pipe is heated, the heat conduction pipe transfers heat energy downwards to the inner heating device at the hot end, and the radiation plate at the lower part of the heat conduction pipe is heated, adopts a copper plate and graphene thermal radiation patch structure, and radiates the heat energy out in an electromagnetic wave mode; the hot end reflecting plate is made of white materials, is arranged on the inner wall of the upper part of the hot end and reflects electromagnetic waves; the liquid level heating adopts a blackbody suspension bead structure, the material is metal or organic matter, the suspension beads can be hollow or solid pellets, and the specific gravity of the suspension beads is smaller than that of the liquid; at the starting position, a layer of black body suspension beads floats on the liquid surface, absorbs electromagnetic waves and converts the electromagnetic waves into heat energy, and the liquid surface is heated; the liquid level temperature of the hot end rises rapidly to generate large saturated vapor pressure, liquid in the pipe is pressed to flow to the cold end, the liquid level of the hot end falls, the liquid level of the cold end rises, the gravity center moves to the support axis, and then the liquid level crosses the support axis to enable the hot end to swing upwards and the cold end to swing downwards; when the liquid level of the hot end drops, the heating plate is extinguished and stops heating, the small balls fall on the metal separation net below the liquid level of the starting position, and the separation net is fixed on the inner wall of the hot end ball. The heat conduction pipe is made of metal with high heat conductivity; the tube type can be an inverted U-shaped tube or a non-inverted U-shaped tube. The heat conduction pipe adopts a structure that a copper pipe is internally provided with a heat conduction medium, or adopts a channel type super heat conduction type heat conduction pipe.
The associated gas liquid level radiation type heating mode adopts a blackbody suspended bead structure or a blackbody barrier structure, a blackbody grid layer is arranged at the liquid level position of the starting hot end, and the blackbody grid layer is fixed on the inner wall of the hot end, absorbs electromagnetic waves and converts the electromagnetic waves into heat energy. The heat head end adopts a radiation type heating mode or a conduction type heating mode, and the conduction type heating mode adopts a suspension heat conduction plate, a heat conduction plate guide mechanism, a heat conduction flexible wire and a heat conduction pipe. External heat energy is conducted to the heat conduction flexible wire through the heat conduction pipe, and the heat conduction flexible wire is conducted to the suspension heat conduction plate; the suspension heat conducting plate is suspended on the liquid level of the hot end to move up and down by virtue of the heat conducting plate guiding mechanism, and the heat conducting plate guiding mechanism limits the heat conducting plate to move back and forth and left and right to prevent the heat conducting plate from impacting the inner wall of the hot end.
The base support frame comprises a base and two vertical and parallel swing cylinder support frames. The foundation base and the swing cylinder support frame are steel structures and are fixed into a rigid whole by bolts. Two semicircular metal tiles of the holder clamp the middle part of the swing cylinder heat energy converter to form a rigid assembly, support shafts on two sides of the holder are horizontal and concentric, the rigid assembly is installed at the upper end part between two swing cylinder support frames through a swing bearing, and the support shafts on the two sides of the swing cylinder heat energy converter are overlapped with the support shafts on the two sides of the holder. The oscillating bearing can be a pair of sliding bearings, and can also adopt a rolling bearing, a sliding sleeve bearing or a magnetic bearing.
The kowtow type associated gas pumping unit is characterized in that an oil pumping horsehead oil extraction mechanism is arranged at the end part of a cold head of the swing cylinder heat energy converter, and a power generation horsehead balance system is arranged at the end part of a hot head. The horse head is used for changing the reciprocating circular motion of the A, B two ends into the vertical linear reciprocating motion. A. The radius of the circular arc surface of the horse head at the end B is equal to the length from the supporting axle center as the circle center to the circular arc surface of the horse head at the end A, B. In order to ensure that the circular motion is changed into linear motion under a certain stroke length, the length of the circular arc surface of the horse head is 1.3 times of the maximum stroke length of the suspension point of the horse head.
The pumping horse head in the pumping horse head oil extraction mechanism drives the polish rod and the pumping rod to do up-and-down reciprocating linear motion through the steel wire rope and the rope hanger; the motion is transmitted to the plunger of the oil well pump through the oil pumping rod, and the kowtow associated gas oil pumping machine drives the oil well pump to work.
And a power generation horse head in the hot head end power generation horse head balance system is connected with a balance straight-moving generator below. The balance straight-moving generator consists of a generator rotor, a generator stator and a power output line. The load of the up-down stroke is uneven when the pumping unit pumps oil, the pumping horsehead needs to pull up the pumping rod string and the oil string during the up stroke, and the pumping rod string can fall down by the dead weight during the down stroke, so that the swing cylinder temperature difference engine does not work very uniformly; in order to make the oil pumping up-down stroke do work evenly, an on-off reversing switch is arranged above the balanced straight-moving generator, the oil pumping rod column falls down when the end B strokes down, the end A swings up, the reversing switch is in an on state, and the generator generates electricity and does work; when the end B reaches the bottom dead center and the end A reaches the top dead center, the reversing switch is touched, the reversing switch is in an open circuit state, underground crude oil is extracted when the end B moves upwards, and meanwhile, the end A swings downwards, and the generator does not generate electricity and does work; when the end B reaches the top dead center and the end A reaches the bottom dead center, the reversing switch turns to restore the access state, when the sucker rod string at the end B falls, the end A swings upwards, and the generator continues to generate power.
The speed and acceleration of the suspension point in the up-down stroke of the pumping unit and the direction of the suspension point are changed. The moving direction of the B end is downward during the downstroke, the acceleration is gradually increased, in order to reduce the inertia impulsive force, the coil spacing of the magnets and the stator coil group in the rotor magnet group in the balanced straight-moving generator adopts the unequal-spacing design, the spacing between the magnets and the spacing between the coils are gradually reduced from bottom to top, the power generation acting resistance is gradually increased when the A end swings upwards, the output current is gradually increased, and the inertia impulsive force during the downstroke of the B end can be reduced.
Because the current output is intermittent, the current magnitude is also changed, the power generation horsehead balance system is designed to be provided with a large-capacity chemical or physical energy accumulator, unstable output current is input into the energy accumulator and then is output to each power utilization device of the kowtow associated gas pumping unit by the energy accumulator, the kowtow associated gas pumping unit is self-sufficient, and the normal working requirement of the kowtow associated gas pumping unit is met.
The power generation horse head balance system can select a balance straight-moving generator or a balance rotating generator. If a balanced rotating generator is adopted, the A end is not provided with a power generation horse head, but a four-bar mechanism is adopted. Because the axle center of the supporting shaft and the axle center of the balanced rotating generator are fixed, a virtual fixed connecting line is formed, so the four-bar linkage comprises: the crank, the connecting rod, the swing cylinder and the supporting shaft are virtually connected with the shaft of the rotary generator. One end of the crank is fixed on the shaft center of the generator, the other end of the crank is rotationally connected with one end of the connecting rod, the other end of the connecting rod is rotationally connected with a specific position on the swinging cylinder, and the swinging cylinder rotates around the shaft center of the supporting shaft to form a four-bar mechanism; the swing of the swing cylinder drives the balance rotation generator to rotate. The stator adopts a half-cycle coil design, when the end A swings upwards during the downstroke of the end B, the crank is pulled from bottom to top, the rotor of the generator is rotated for half a cycle, and the magnet group on the rotor cuts the magnetic lines of the stator coils to generate power; and the other half-cycle stator is not provided with a coil, when the end B strokes upwards, the end A swings downwards, the crank is pulled from top to bottom, and the rotor of the generator is rotated for half cycle again without generating power.
In order to finely adjust the position of a supporting shaft when the kowtow type associated gas pumping unit works, a balancing weight is installed at the cold head end of a swing cylinder, and the farther the balancing weight is away from the supporting shaft, the lower the position of the bottom dead center of the cold head end is.
The rope hanger comprises slip teeth, an upper supporting plate, a lower supporting plate, a jackscrew and the like, and the steel wire rope and the polished rod are connected into a whole; the indicator can be arranged on the rope suspension device to measure a suspension point indicator diagram.
The associated gas storage tank safety system consists of a gas storage tank, a gas transmission pipe, a gas transmission hose and a gas leakage monitoring and protecting device; the gas storage tank is far away from the oil pumping unit swing cylinder heat energy converter; the gas leakage monitoring signal is connected with the oil pumping machine controller, and when an abnormal condition occurs, the oil pumping machine controller starts a protection device or dispels accidental overproof associated gas, reduces the concentration or shuts down and overhauls.
The oil pumping machine control system comprises a swing cylinder heat energy converter pressure sensor, a temperature sensor, a pressure limiting valve, a speed and angle sensor, an electronic igniter, a power indicator, a safety system signal generator, an oil pumping machine controller and the like. Various sensors and signal generators are wirelessly connected with the pumping unit controller. Once the pendulum cylinder heat energy converter is abnormal, the pressure sensor and the temperature sensor can give an alarm in advance, and the pumping unit controller sends out a protection instruction. Speed and angle sensors may monitor the device operating conditions and adjust the device operation to an optimum through electronic igniters and the like. The controller is wirelessly connected with each monitoring instrument, receives various monitoring signals, sends control instructions to each execution device through internal control software and maintains the normal work of the kowtow associated gas pumping unit; meanwhile, various data and video pictures are remotely sent to the headquarter control room through the internet, so that the monitoring and the remote control of the headquarter control room can be achieved.
Advantageous effects
1, the equipment adopts the self-produced crude oil associated gas which is originally emptied and burnt as fuel to replace electric energy, can reduce the oil production cost by 25% -30%, and has high economical efficiency.
2, the swing drum temperature difference engine in the device is a novel heat engine, the device is simple, and the energy efficiency is high.
3, the equipment has good operability and can conveniently realize intelligent remote monitoring operation.
4, the electricity generated by the power generation horsehead balance system of the equipment can meet various power consumption requirements of the equipment, and a cable does not need to be laid for a long distance.
5, the device does not generate high-temperature, high-pressure and high-speed steam, the safety of the device is good, the maintenance cost is low, the device runs noiselessly and the service life is long.
Drawings
The invention is further illustrated with reference to the following figures and examples.
Fig. 1 is an overall schematic diagram of the kowtow associated gas pumping unit of the invention.
FIG. 2 is a front perspective view of a pendulum cylinder thermoelectric engine thermal energy converter in a horizontal position with liquid.
FIG. 3 is a front perspective view of a liquid in a starting position of a thermal energy converter of the swing-barrel temperature differential engine.
Fig. 4 is an anatomical schematic diagram of a thermal head end heating system of a pendulum cylinder temperature difference engine thermal energy converter.
FIG. 5 is a structural exploded view of relevant components of the swing barrel temperature difference engine.
Fig. 6 is a schematic structural diagram of an oil pumping horsehead of a kowtow-type associated gas oil pumping unit.
Fig. 7 is an enlarged reversing schematic diagram of a power generation horsehead power generation reverser of a kowtow associated gas pumping unit.
Fig. 8 is a schematic cross-sectional view of a cylindrical balanced inline generator.
FIG. 9 is a circuit diagram of the on-off operation of the non-contact electromagnetic monitor.
In the figure: 1. the pendulum barrel temperature difference engine comprises D1-a hot end ball diameter, D2-a cold end ball diameter, D-an intermediate pipe diameter, 2, a pendulum barrel heat energy converter, 3, an oil pumping horse head, 4, a power generation horse head, 5, a burner windshield, 6, a sliding block balance regulator, 7, an associated gas hard pipe, 8, an associated gas hose, 9, an oil pumping steel wire rope, 10, a power generation steel wire rope, 11, a pumping unit support frame, 12, a magnetic shield plate, 13, an oil pumping polished rod eye, 14, a power generation commutator support, 15, a power generation commutator, 16, a power generation polished rod eye, 17, an oil pumping polished rod, 18, a power generation polished rod, 19, an associated gas storage tank, 20, a mobile intelligent leak detector, 21, a support frame base, 22, a generator rotor, 23, a generator stator, 24, a power output line, 25, a storage battery, 26, an intelligent controller, 27, an oil gas output pipe, 28 and an associated, 29. associated gas overproof blower 30, foundation 31, support axis 32, long tubular container 33, small ball container 34, large ball container 35, ball-tube welding position 36, liquid refrigerant 37, balance axis 38, B end gas refrigerant 39, A end gas refrigerant 40, pressure sensor 41, temperature sensor 42, pressure limiting valve 43, heat radiation plate 44, electronic igniter 45, heating plate 46, inverted U-shaped heat conduction tube 47, white body plate-inner shell welding position 48, radiation plate 49, white body plate 50, black body suspension bead 51, suspension bead spacer net 52, A end liquid level 53, B end liquid level 54, non-contact electromagnetic monitor 55, support frame threaded hole 56, axle semicircular metal tile 57, semicircular metal tile 58, metal central hole concentric axle 59, cone, 60. cone head jackscrew, 61, jackscrew fixing nut, 62, tile threaded hole, 63, tile through hole, 64, tile fastening bolt, 65, monitor magnet, 66, spring, 67, monitor switch, 68, monitor signal generator, 69, suspension bead isolation mesh hole, 70, A end hemisphere spherical shell section, 71, base support frame connecting bolt (6), 72, horse head-spherical welding line, 73, horse head steel plate, 74, positioning U groove, 75, steel plate fastening screw hole (6), 76, steel plate fastening through hole (6), 77, steel plate fastening bolt (6), 78, steel wire rope fastening screw hole (2), 79, steel wire rope cap through hole (2), 80, steel wire rope cap, 81, steel wire rope fastening bolt (2), 82, permanent magnet commutation trigger (2, opposite magnetic pole direction), 83, commutator magnet, 84, magnet insulation support, 85. the generator comprises a conductive copper plate, 86, a rotor magnet, 87, stator coils, 88, a generator fixing bolt through hole, 89, a power generation polished rod connecting rod hole, 90, the section of a welding part between a ball pipe and a pipe, 91, a generator fixing bolt, 92, a power generation polished rod connecting rod, 93, a connecting rod cotter pin, 94 and a cylindrical balance straight-moving generator.
Detailed Description
The head-knocking type associated gas oil pumping machine comprises: the device comprises a swing cylinder temperature difference engine (1), an oil pumping horsehead (3), a power generation horsehead (4), a sliding block balance regulator (6), an oil pumping machine support frame (11), an associated gas storage tank (19), an intelligent controller (26) and the like, and is shown in figure 1. Petroleum associated gas in an associated gas storage tank (19) is input into a swing drum temperature difference engine (1) through an associated gas hard pipe (7) and an associated gas hose (8), heat energy is converted into mechanical energy through combustion, and the swing of the swing drum temperature difference engine (1) around a support axis (31) is started. The oil pumping horsehead (3) at the cold end is swung downwards, and the power generation horsehead (4) is swung upwards to drive the power generator rotor (22) to generate power upwards; (3) when the lower dead point is reached (4) and the upper dead point is reached, the power generation commutator (15) is triggered, the power output is in an open circuit, and the upper half graph of the graph in FIG. 7 is shown; the oil pumping horsehead (3) pulls the oil pumping steel wire rope (9), the oil pumping polished rod eye (13) and the oil pumping polished rod (17) to move upwards, (17) the movement is transmitted to a plunger in an oil well pump at the bottom of the well through an underground oil pumping rod, the lifted crude oil and associated gas are output through an oil gas output pipe (27), the associated gas is collected to an associated gas storage tank (19) at a remote place, and the oil pumping horsehead (3) does not generate power in the swinging process. (3) Upward swinging to a top dead center, (4) downward swinging to a bottom dead center, triggering a power generation commutator (15), and enabling power output to be in a pass state, as shown in a lower half diagram of fig. 7; the rear part (3) starts to swing downwards, the power generation horsehead (4) starts to swing upwards, the power generation steel wire rope (10), the power generation rope hanger (16), the power generation polished rod (18) and the power generator rotor (22) move upwards together, and (94) power generation is performed to do work; the generated electric energy enters a storage battery (25) through an electric power output line (24).
The swing barrel temperature difference engine (1) mainly comprises a swing barrel heat energy converter (2), a heat dissipation plate (43), an internal and external heating device of an associated gas liquid level heating system, an oil pumping machine support frame (11), a non-contact electromagnetic monitor (54) and different sensors. (1) Operating under the control of an intelligent controller (26).
The pendulum cylinder heat energy converter (2) is a dumbbell-shaped special aluminum alloy sealed container, and is formed by welding a long tubular container (32) and two spherical containers with different spherical diameters, as shown in figure 2. (32) Is cylindrical; the small ball head container (33) and the large ball head container (34) are hollow spherical balls. (32) The ball joint (33) and the joint (34) are sleeved in place and then sealed in a welding mode, namely a ball-pipe welding part (35); after vacuum pumping, a certain amount of liquid refrigerant (36) is injected into the aluminum alloy sealed container, and liquid and vapor thereof cannot overflow. The large bulb container (34) is a hot-head end-A end, and the small bulb container (33) is a cold-head end-B end. Finding the balance axis (37) and the support axis (31) of (2), the center of gravity being at the right side A end of the support axis (31), see FIG. 2; the A end is arranged downwards, the B end is arranged upwards, liquid partition spaces with gas at the A end and the B end, gaseous refrigerants (38) at the B end, gaseous refrigerants (39) at the A end and liquid refrigerants (36) are formed in a special sealed container, and the liquid partition spaces are shown in figure 3; the pendulum cylinder heat energy converter (2) is provided with a pressure sensor (40), a temperature sensor (41) and a pressure limiting valve (42). (2) A heat dissipation plate (43) is installed inside. (2) The heat dissipation plates (43) in the middle pipe are distributed along the length direction of the pipe, and the heat dissipation plates (43) are made of aluminum or aluminum alloy and are welded on the inner wall of the pipe; the heat dissipation plate (43) at the head part of the A end is arranged at the lower part in the head and is welded into a grid distribution, as shown in figure 4.
The outer heating device of associated gas liquid level heating system includes: an electronic igniter (44), a heating plate (45), an inverted U-shaped heat pipe (46), a burner windshield (5), and the like. The associated gas hose (8) is connected with an electronic igniter (44), and the electronic igniter (44) receives an instruction sent by the intelligent controller (26), and the heating plate (45) is ignited by ventilation or the heating plate (45) is extinguished by cutting off gas; the heating pan (45) heats (46) the top of the inverted U, transferring heat energy downward into the associated gas internal heating means in end a, see fig. 4. The burner windshield (5) prevents the influence of ambient flowing air on the combustion (45), see fig. 1.
The internal heating device of the associated gas liquid level heating system comprises: the heat pipe comprises an inverted U-shaped heat pipe (46), a radiation plate (48), a white body laminate (49), black body suspension beads (50) and suspension bead separation nets (51). The inverted U-shaped heat pipe (46) in the A end conducts heat energy to the radiation plate (48), the radiation plate (48) radiates infrared electromagnetic waves, and the radiation energy can be directly transmitted to the blackbody suspension bead (50) floating on the liquid level of the A end or reflected by the white body laminate (49) and is converted into heat energy to heat the liquid level (52) of the A end. The white body layer plate (49) and the suspension bead separation net (51) are fixed on the inner wall of the sphere at the A end in a welding mode, and the (47) is the welding position of the white body layer plate and the inner shell as shown in figure 4.
Energy conversion: the temperature of the liquid level (52) at the A end is increased while the temperature of the liquid level (53) at the B end is unchanged, the vapor pressure difference at the two ends is increased, the liquid refrigerant (36) in the pipe is pressed to flow to the B end, the liquid level (52) at the A end is lowered, the liquid level (53) at the B end is raised, the gravity center is caused to move to the support axis (31) and then cross the support axis (31), the A end is swung upwards, and the B end is swung downwards; in the process of the end B swinging downwards, as more liquid refrigerant (36) in the pipe flows to the head part of the end B, the downward moment is gradually increased, and the action of the dynamic pressure head is added, the swinging is accelerated; when the swing arm swings to the vicinity of the horizontal position, the gas refrigerant (38) at the end B and the gas refrigerant (39) at the end A are communicated, the gas pressure difference between the two ends is zero, and the dynamic pressure head is also zero. At the moment, the gravity center returns to the end A which is in the horizontal position, the moment of the end A is increased, the end A begins to swing downwards, the liquid refrigerant (36) flows to the head of the end A and returns to the starting position, and the two ends A and B return to the liquid separation space of the original two air chambers to finish a movement period.
According to the thermodynamic phase change theory, liquid refrigerant (36) in the container is pressed towards the B-side, the gas space of gaseous refrigerant (38) at the B-side is compressed, the vapor pressure of (38) increases, and the corresponding equilibrium temperature increases. The temperature of the gas-liquid two phase equilibrium at the cold head end is lower than the equilibrium temperature corresponding to the vapor pressure after the temperature is raised, and a condensed liquid medium is generated on the inner surface of the shell at the cold head end (53); the condensed liquid medium is collected into the liquid refrigerant (36) in the shell (2), and the phase change heat is dissipated to the outside air through the shell. The process is continued until the swinging cylinder heat energy converter (2) swings to the position near the horizontal position, and the gas is communicated at two ends. In the case of the hot head end (end a), the liquid level (52) at the end a is heated, the temperature rises, the corresponding equilibrium saturated vapor pressure rises, and a condensed liquid medium is also generated on the inner surface of the shell at the hot head end, but the evaporation speed is much higher than the condensation speed; on the other hand, the heating device is arranged on the upper part of the hot head end, the inverted U-shaped heat conduction pipe (46) is inserted into the shell and welded with the shell, and part of heat transferred by the heat conduction pipe (46) can be transferred to the shell on the upper part of the hot head end, so that the temperature of the shell is increased, the output of a condensed liquid medium is reduced, and the liquid refrigerant (36) in the container is not influenced to be pressed towards the cold head end.
The working mechanism of the swing barrel temperature difference engine (1) is as follows: when the end A reaches a low position (starting position), the liquid level (52) of the end A rises to a high position; the black body suspension bead (50) is a black organic matter hollow sphere, and is suspended and covered on the A-end liquid level (52); the magnetic shielding plate (12) installed on the lower abdominal part of the end A is inserted into a non-contact electromagnetic monitor (54) installed on a support frame base (21), the non-contact electromagnetic monitor (54) is powered on, signals are sent to an intelligent controller (26), and the instruction is sent to an electronic igniter (26), so that an associated gas hose (8) is opened by the electromagnetic monitor (44) and a heating plate (45) connected with the associated gas hose (8) is ignited, the heating plate (45) is burnt, the top of the inverted U-shaped part of the heating plate (46) is heated, external heat energy is downwards transmitted into the end A, a radiation plate (48) connected with the heating plate (46) is heated, the heat energy is converted into electromagnetic wave radiation energy, (48) the electromagnetic wave radiation energy is directly radiated or reflected by a white body laminate (49), the electromagnetic wave radiation energy is transmitted to a suspended bead (50) layer suspended and covered on the liquid level (52) of the end A, and the radiation energy. (52) The temperature rises rapidly to generate large saturated vapor pressure, liquid refrigerant (36) in the pipe is pressed to flow to the end B, the liquid level (53) at the end B rises, the end A swings downwards at the end B, the (52) in the end A descends, the black body suspension bead (50) layer also descends, and after reaching the suspension bead separation net (51), the (50) is separated from the (52); when the end A swings upwards and the end B swings downwards, the magnetic shielding plate (12) is separated from the non-contact electromagnetic monitor (54), the intelligent controller (26) receives a closing signal of the monitoring signal generator (68), sends an instruction to the electronic igniter (44), the associated gas hose (8) is closed, and the heating plate (45) extinguishes fire. When the two ends of A, B swing to the vicinity of the horizontal position, the moment of the end A becomes larger again, and starts to swing downwards again, the liquid refrigerant (36) flows to the end head part of the end A and returns to the starting position, the two ends A and B return to the liquid separation space of the original two air chambers, a movement cycle is completed, and (1) ignition heating starts again. Thus, the thermal energy is continuously converted into mechanical energy by intermittent cyclic heating.
The oil pumping machine support frame (11) is connected with the support frame base (21) into a rigid whole by 6 base support frame connecting bolts (71), the upper parts of the two support frame support frames (11) are respectively provided with a support frame threaded hole (55), and the two support frame threaded holes (55) are concentric and horizontal. The middle part of the pendulum cylinder heat energy converter (2) is clamped by the semicircular metal tile piece (57) and the semicircular metal tile piece (56) with the shaft, and the axis of the concentric shaft (58) of the metal tile piece is superposed with the supporting axis (31). Four tile fastening bolts (64) are screwed into tile threaded holes (62) through tile through holes (63) so that the pendulum cylinder heat energy converter (2) is clamped by the tile fastening bolts (57) and the tile fastening bolts (56) to form an assembly. The combined assembly is placed between two oil pumping machine support frames (11), conical center holes (59) of two outer end faces of a metal tile concentric shaft (58) are aligned with support frame threaded holes (55), a conical jackscrew (60) with threads is screwed in from the two support frame threaded holes (55), the conical center hole (59) is jacked in the conical head of the conical jackscrew (60), two jackscrew fastening nuts (61) are screwed in from the outer ends of the two conical jackscrews (60), the two conical jackscrews (60) are fixed on the two oil pumping machine support frames (11), a pair of sliding bearings are formed, and the swing cylinder temperature difference engine (1) can swing with low damping.
The non-contact electromagnetic monitor (54) is arranged on a support frame base (21) below the swing cylinder heat energy converter (2). The magnetic shielding plate (12) is fixed on the lower abdomen of the end A and swings together with the end A, the non-contact type insertion (54) shields the magnetic force line of the monitor magnet (65) when in a starting position, the tension of the spring (66) is greater than the suction force of the spring (65), the monitoring switch (67) is pushed to move right, and the circuit of the non-contact type electromagnetic monitor (54) is switched on, as shown in figure 9. The monitoring signal generator (68) sends a switching-on signal to the intelligent controllers (26, 26) to send a command, and the electronic igniter (44) works. When the end A starts to swing upwards, the magnetic shielding plate (12) is separated from the non-contact electromagnetic monitor (54), the monitoring switch (67) moves leftwards, the circuit is closed, and the circuit (26) receives (68) a closing signal and sends a fire stopping instruction to the circuit (44), as shown in figure 9.
The schematic diagram of the oil pumping mule head mechanism of the head-breaking associated gas oil pumping machine is shown in fig. 6, and the arc radius of the oil pumping mule head (3) is the length R1 from the supporting axis (31) as the circle center to the arc surface of the oil pumping mule head (3). The oil pumping horsehead (3) is made of aluminum alloy and is welded with the small ball head container (33) into a whole, namely a horsehead-spherical welding line (72). The horsehead steel plate (73) with the same thickness is attached to the arc surface of the horsehead (3) and is fixed on the oil pumping horsehead (3) through the steel plates (75), (76) and (77). A positioning U-shaped groove (74) is designed at the contact area of the oil pumping steel wire rope (9) of the (73), a steel wire rope cap (80) is arranged at the upper head part of the (9), and the upper head part of the (9) is fixed at the upper part of the (74) through the (81), (79) and (78). The structure of the oil pumping polished rod eye (13) is the same as that of the electric head knocking machine, and the description is omitted. (13) Connecting (9) and (17) into a whole; (13) a dynamometer is arranged on the suspension point, and a suspension point indicator diagram is measured; (17) driving the pumping rod to do up-and-down reciprocating linear motion; the motion is transmitted to the plunger of the oil well pump at the bottom of the well through the sucker rod.
The schematic diagram of the power generation horsehead mechanism is shown in figure 7. The structure of the power generation horsehead (4) is the same as that of the oil pumping horsehead (3), and the details are not repeated, but the arc radius R2 is smaller than R1. One end of the power generation commutator bracket (14) is fixed in the middle of the oil pumping machine support frame (11), and the other end is provided with a power generation commutator (15). The power generation horse head (4) is connected with a generator rotor (22) of a lower cylindrical balance straight generator (94) through (10), (16) and (18). The permanent magnet reversing trigger (82) is provided with two permanent magnet reversing triggers, one permanent magnet reversing trigger is arranged on the generator steel wire rope (16), the other permanent magnet reversing trigger is arranged on the generator steel wire rope (10) at the upper end, the polarities of the working surfaces are opposite, and the generator commutator (15) is shown in figure 7 and comprises a commutator magnet (83), a magnet insulating support (84), a conductive copper plate (85) and the like. (84) The two supports (83) are fixed at the corresponding positions of the bottom surface (84) by the two supports (85). When the end B goes down, the sucker rod string falls; the end A swings upwards, (15) is in a passage state, and (94) generates electricity and does work; when the end B reaches the bottom dead center and the end A reaches the top dead center, the N pole of the N pole pair (82) of (83) is pushed away, (85) is separated from the contact of the power output line (24), (15) is switched to an open circuit state, as shown in the upper half diagram of fig. 7, the end A swings downwards when the end B goes up, the end B draws underground crude oil, and the end A (94) does not generate electricity and do work; when the end B reaches the top dead center and the end A reaches the bottom dead center, the S pole of the N pole pair (82) of (83) is sucked back, (83) contacts with a contact of the power output line (24), (15) is switched to be in a passage state, the end A swings upwards when the rod string at the end B falls, and (94) power generation can be continued.
The moving direction is downward when the end B is downstroke, the acceleration is gradually increased, in order to reduce the inertia impulsive force, the distance between rotor magnets (86) in a magnet group of a rotor (22) of a generator in a cylindrical balance straight-moving generator (94) and the distance between stator coils (87) in a coil group of a stator (23) of the generator adopt an unequal-distance design, see fig. 8, the distance between the rotor magnets (86) and the distance between the stator coils (87) are gradually reduced from bottom to top, the power generation acting resistance is gradually increased when the end A swings upwards, the output current is gradually increased, and the inertia impulsive force when the end B is downstroke can be reduced. The generator fixing bolt (91) fixes the cylindrical balance straight generator (94) on the support frame base (21) through the generator fixing bolt through hole (88). The power generation polished rod connecting rod hole (89) can connect the generator rotor (22) with the power generation polished rod (18) through the power generation polished rod connecting rod (92). (93) Is a connecting rod cotter pin.
In addition, considering that the current output is intermittent and the current magnitude is also variable, the power generation horsehead balance system is provided with a storage battery (25), unstable output current is continuously input into the storage battery (25), and then the unstable output current is output to each power utilization device of the kowtow associated gas pumping unit through the storage battery (25), so that the kowtow associated gas pumping unit is self-sufficient and meets the normal working requirement of the kowtow associated gas pumping unit. See fig. 1.
The associated gas storage tank safety system consists of an associated gas storage tank (19), an associated gas transmission hard pipe (7), an associated gas hose (8), an associated gas leak detector (28), an associated gas standard exceeding blower (29) and a mobile intelligent leak detector (20), and is shown in figure 1; (19) away from (1); (28) and (20) the detection signal is connected with an intelligent controller (26), and when an abnormal condition occurs, (26) a protection device is started, or accidental overproof associated gas is dispersed, and a normal value is recovered, or shutdown and maintenance are carried out.
Claims (10)
1. A kowtow formula associated gas beam-pumping unit, characterized by: a swing cylinder of a swing cylinder temperature difference engine in the oil pumping unit is used for replacing an electric kowtow engine walking beam which swings up and down; the pendulum cylinder temperature difference engine directly converts heat energy into mechanical energy by taking petroleum associated gas as a heat source, drives the pendulum cylinder to swing up and down, and replaces a motor of the electric head knocking machine; the base support frame supports a swing cylinder heat energy converter of the swing cylinder temperature difference engine, and a certain amount of low-boiling-point liquid is injected into the converter after the converter is vacuumized; the heat head end is provided with an external combustion and internal guide associated gas liquid level heating system; the power generation horsehead is arranged outside the hot head end to drive the balance straight-moving generator to work, and the generated electric energy meets the requirements of various power utilization devices in the kowtow type associated gas oil pumping unit; an oil pumping mule head is arranged outside the cold head end to drive an oil pumping mechanism to work and pump out oil and associated gas; and the safety system of the associated gas storage tank and the control system of the oil pumping unit ensure the safe operation of the head-knocking type associated gas oil pumping unit.
2. The kowtow associated gas pumping unit of claim 1, characterized by: the liquid level radiation type heating mode of the associated gas at the hot end adopts a blackbody suspended bead structure or a blackbody grating structure, a blackbody grating layer is arranged at the liquid level position of the starting hot end, and the blackbody grating layer is fixed on the inner wall of the hot end.
3. The kowtow associated gas pumping unit of claim 1, characterized by: the radiation plate adopts a copper plate and graphene heat radiation patch structure; the heat conduction pipe adopts a structure that a copper pipe is internally provided with a heat conduction medium, or adopts a channel type super heat conduction type heat conduction pipe.
4. The kowtow associated gas pumping unit of claim 1, characterized by: the hot end reflecting plate is made of white materials and is arranged on the inner wall of the upper part of the hot end to reflect electromagnetic waves.
5. The kowtow associated gas pumping unit of claim 1, characterized by: the liquid level at the end of the thermal head adopts a radiation type heating mode or a conduction type heating mode, external heat energy is conducted to a heat conduction flexible wire through a heat conduction pipe, and the heat conduction flexible wire is conducted to the suspension heat conduction plate; the suspension heat conducting plate is suspended on the liquid level of the hot end to move up and down by virtue of the heat conducting plate guiding mechanism, and the heat conducting plate guiding mechanism limits the heat conducting plate to move back and forth and left and right to prevent the heat conducting plate from impacting the inner wall of the hot end.
6. The kowtow associated gas pumping unit of claim 1, characterized by: an oil pumping mule head oil extraction mechanism is arranged at the end part of a cold head of the knocking head type associated gas oil pumping machine, and a power generation mule head balance system is arranged at the end part of a hot head; the donkey head is used for changing the reciprocating circular motion of the two ends of the hot head and the cold head into vertical linear reciprocating motion; the radii of the hot head end donkey head arc surfaces and the cold head end donkey head arc surfaces are equal to the lengths from the supporting axis as the circle center to the hot head end donkey head arc surfaces and the cold head end donkey head arc surfaces respectively.
7. The kowtow associated gas pumping unit of claim 1, characterized by: an on-off reversing switch is arranged above the balanced straight-moving generator, the sucker rod string falls down when the cold head end goes down, the reversing switch is in an on state, and the generator generates electricity and applies work; when the cold end reaches the bottom dead center and the hot end reaches the top dead center, the reversing switch is touched, the reversing switch is in an open circuit state, underground crude oil is extracted when the cold end moves upwards, and meanwhile, the hot end swings downwards, and the generator does not generate electricity and does work; when the cold end reaches the upper dead point and the hot end reaches the lower dead point, the reversing switch turns to restore the access state, the hot end swings upwards when the sucker rod string at the cold end falls, and the generator continues to generate power.
8. The kowtow associated gas pumping unit of claim 1, characterized by: the distances between the magnets and the coils of the stator coil group in the rotor magnet group in the balanced straight-moving generator are designed in an unequal mode, the distances between the magnets and the distances between the coils are gradually reduced from bottom to top, the power generation acting resistance is gradually increased when the end A swings upwards, and the output current is gradually increased.
9. The kowtow associated gas pumping unit of claim 1, characterized by: the power generation horse head balance system can select a balance straight-moving generator or a balance rotating generator; if a balance rotating generator is adopted, the hot head end is not provided with a power generation horse head, a four-bar mechanism is adopted, the swing of the swing cylinder drives the balance rotating generator to rotate, and the stator adopts a half-cycle coil design.
10. The kowtow associated gas pumping unit of claim 1, characterized by: the associated gas storage tank safety system consists of a gas storage tank, a gas transmission pipe, a gas transmission hose and a gas leakage monitoring and protecting device; the gas storage tank is far away from the swing cylinder heat energy converter of the pumping unit; the gas leakage monitoring signal is connected with the oil pumping machine controller, and when an abnormal condition occurs, the oil pumping machine controller starts a protection device or dispels accidental overproof associated gas, reduces the concentration or shuts down and overhauls.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN113739866A (en) * | 2021-08-30 | 2021-12-03 | 株洲齿轮有限责任公司 | Residual oil amount control method for new energy oil cold-electric drive system on production line |
CN114951714A (en) * | 2021-02-18 | 2022-08-30 | 丰田自动车株式会社 | Lifting device and workpiece processing system |
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2020
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN114951714A (en) * | 2021-02-18 | 2022-08-30 | 丰田自动车株式会社 | Lifting device and workpiece processing system |
CN113739866A (en) * | 2021-08-30 | 2021-12-03 | 株洲齿轮有限责任公司 | Residual oil amount control method for new energy oil cold-electric drive system on production line |
CN113739866B (en) * | 2021-08-30 | 2024-01-23 | 株洲齿轮有限责任公司 | Residual oil quantity control method of new energy oil-cooled electric drive system on production line |
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