CN115823200A - Active power increasing machine for increasing negative power moment of negative force arm of lever through serially-connected crossed levers - Google Patents

Abstract

The invention discloses a main power increasing machine for increasing the negative power working distance of a negative force arm of a lever by serially connecting crossed levers.A push rod end hole of a straight motor is connected with main force holes of a group of short bent levers connected in parallel, a pull and push hole of the short bent lever is connected with one end support hole of a group of parallel support rods without edges, and the other end support hole of the parallel support rods is connected with the main force hole of a group of parallel pressure pry rods; the supporting hole of the parallel short bent lever is connected with the supporting hole of the other group of parallel supporting rods, the supporting hole of the other end of the group of parallel supporting rods is connected with the supporting hole of the press pry bar, the negative force hole of the short bent lever is connected with the force transmission hole of the group of parallel additional cross levers, and the supporting point hole of the group of parallel additional cross levers is connected with the supporting point hole of the press pry bar. The main power booster has the advantages of simple structure, convenient use, simple shapes of various parts, easy manufacture, low cost, no combustion of fuel for producing carbon dioxide, no emission of carbon dioxide, environmental protection and capability of becoming permanent mechanical energy for human beings.

Description

Active power increasing machine for increasing negative power moment of negative force arm of lever by serially-connected crossed levers

Technical Field

The invention belongs to the technical field of negative power moment of a negative force arm of an increasing lever of a series cross lever, and particularly relates to a main power increasing machine for increasing the negative power moment of the negative force arm of the increasing lever of the series cross lever, which can be suitable for providing power for assembling vehicles running on a road, providing power for assembling railway locomotives, and providing power for assembling ships and generators.

Background

To date, there are five types of man-made power machines, including petroleum-fired internal combustion power machines, coal-fired power machines, electric motors, nuclear power machines, and fuel-fired turbines. The waste gas discharged by the power machine of the oil burning series and the power machine of the coal burning series is carbon dioxide. The electric motor requires a coal fired power plant or an expensive nuclear powered power plant to supply power. Coal and nuclear materials are limited in nature, and the thick and heavy housing of a nuclear reactor is made of high-grade stainless steel smelted from rare earth elements, which is very expensive.

The prior technical equipment at present comprises five types of internal combustion engines, electric motors, steam engines, nuclear energy machines and fuel turbines. The internal combustion engine shell is divided into three parts, the upper part is a top cover, and the internal combustion engine shell has the function of fixedly mounting a cam and a valve. The middle part is a machine body, and is provided with an assembling cylinder and an oil hanging pump. The lower part is a base for mounting a crankshaft. The main functional parts are an oil pump, a cam, a valve, a cylinder, a piston, a connecting rod and a crankshaft. The valve is installed in the top cap, and the cam is installed outside the top cap on, and the top cap is installed on the trunk body, and the valve is facing to on the cylinder position, and the cylinder dress is internal at the trunk, and in the piston was packed into the cylinder, piston and connecting rod tip were connected, and the connecting rod main aspects is connected with the armshaft top connecting rod position of bent axle, and the trunk body dress is on the base, and the axle bush position of bent axle is laid on the axle bush position of base simultaneously. The main problem is that the oil pump injects oil into the cylinder for combustion, so as to push the piston to move forward and generate power. The waste gas is discharged in the return stroke, no power is generated, only air suction is performed in the forward stroke of the piston for the second time, no power is generated, air compression is performed in the return stroke for the second time, no power is generated, negative force of the air compression is generated, oil injection and combustion are performed in the cylinder in the third stroke, the piston is pushed to generate the power, namely three quarters of time is consumed for generating the power by performing oil injection and combustion in the cylinder for one time, namely the power generated by the piston under the pushing of fuel oil combustion is divided by four; the second problem is that the internal combustion engine is an oil-burning power machine, consumes atmospheric oxygen and discharges carbon dioxide; the third problem is that the cost is high, and the oil is bought continuously. 2. The motor comprises copper coils in shell stator, inner rotor, shell stator, and some direct current motor's shell stator and inner rotor all have copper coils, and inner rotor installs in shell stator, and the main problem is: 1. generally, the motor is used fixedly and cannot move, and the power supply wire cannot move. Two conditions are required for the motor to be used for moving, one of which is to carry a rechargeable battery whose cost is several times that of the motor. Two conditions are that the power supply line is installed on a fixed running road, so that there is a limitation in using the motor. Two problems are that the motor has expensive copper material. Three problems are that the electricity is required to be bought by continuously spending money and the use cost is high. The main equipment of the coal burning steam engine is a one-off tubular coal mill with the length of about twenty meters and the caliber of more than one meter and two meters, a multilayer annular groove is arranged in the coal mill, the wall of the coal mill is provided with a one-off tubular coal mill with the thickness of dozens of centimeters, or a plurality of coal mills with short annular grooves and short tubes, and a large steel ball with the diameter of about one meter is arranged on the annular groove in the coal mill; the pulverized coal conveying belt machine comprises a pulverized coal conveying belt machine, a funnel, a blower, a furnace, a pot, a pipeline and a turbine. Disposable long tube coal roller slant is laid, the port is facing to fine coal conveying belt machine down, the conveyer belt machine other end is facing to the big mouth on the funnel, the osculum is facing to the hair-dryer under the funnel, the hair-dryer is facing to the fire door, the pot is installed to the stove top, adorn water in the pot, install the pipeline on the pot, the turbine one end is installed to the pipeline other end, the coal cinder gets into from the coal roller upper end, the tubulose coal roller is rotatory, the steel ball rolls on the annular and rolls the coal cinder, the coal cinder rolls through the multilayer steel ball, last coal powder is exported on the conveyer belt from the coal roller lower port, send to the big mouth and pour into on the funnel, the osculum spills under the funnel, blow into the burning in the stove by the hair-dryer, burn the water in the pot into vapor and export from the pipeline, the blade that drives the turbine is rotatory, it drives the turbine shaft and drives the rotatory power generation of generator again. The main problems are as follows: 1. the inner wall of the pot is pasted with a layer of calcium carbonate dirt for a long time, the heat conductivity of the calcium carbonate dirt is low, the heat exchange rate is reduced, the steam quantity is also reduced, and the power of a turbine is reduced; 2. the long-tube coal mill is nearly thousand tons, nearly thousand tons of molten steel can not be poured in a general steel plant, and particularly, a plurality of layers of ring grooves in the long-tube coal mill are not easy to machine, so that a plurality of power plants use the short-tube coal mill with one layer of ring grooves, but a plurality of coal mills are needed, and steel balls are not easy to machine. Thirdly, the water consumption is high, and about one hundred kilograms of water vapor is sprayed into the turbine in one second. Fourthly, continuously spending money to buy coal and water. Fifthly, atmospheric oxygen is consumed, and carbon dioxide is discharged. A nuclear power machine: the boiler is mainly used for power plants, the shell of a nuclear reactor is generally a boiler with the diameter of several meters, the height of about ten meters and the wall thickness of dozens of centimeters, stainless steel smelted by expensive rare earth element alloy is filled in the boiler, expensive distilled water for avoiding calcium carbonate dirt generation and three percent of uranium 235 bar stock are arranged in the boiler, a cover with the thickness of dozens of centimeters and the diameter of several meters is arranged above the boiler, a water vapor pipeline is arranged on the cover, and the pipeline leads to a large turbine. In addition, a water pump with the weight of more than two hundred tons presses cold water into the boiler through a pipeline, and the nuclear fission material uranium 235 generates several thousand-degree high temperature in the fission reaction in the boiler, so that several hundred kilograms of water vapor generated in the boiler for 1 second are sprayed to the turbine. The main problems are that: the rare earth elements are consumed more, a kiloton boiler is rare earth element alloy stainless steel which is difficult to smelt, a common steel mill is difficult to smelt, kiloton-level molten steel is difficult to cast at one time, nuclear fission materials are rare in storage capacity on the earth, the ore grade is low, the nuclear fission materials are purified through a plurality of chemical procedures after smelting, and about thousands of high-speed centrifuges are required to carry out high-speed multiple centrifugal purification. The nuclear power machine is also matched with a plurality of high-tech devices, and the nuclear power machine can be built only with the investment of billions of yuan. Oil-fired turbines, which are kerosene-fired drive turbines, are not power plant water-jet steam driven turbines. The kerosene burning turbine is mainly used for the power of an airplane, and is secondly used for the power of a tank, and the kerosene burning turbine consists of a compressor fan blade, a turbine shaft, an oil nozzle, an oil pipe, an oil pump, an oil conveying motor, a shell, a generator and a starting battery. The air compressor fan blade is inserted into the front end of a turbine shaft, twenty-three blades are arranged, twenty-thirty turbine blades are inserted into the rear end of the turbine shaft, the turbine shaft is arranged on a bearing in a shell, the air compressor fan blade is arranged at an air inlet, the turbine blades are arranged at an air jet, an oil nozzle is arranged on the inner wall of the shell between the air compressor fan blade and the turbine blades in the shell, an oil pipe of the oil nozzle penetrates out of the shell and is connected onto an oil pump, the oil pump is connected with a motor, a motor wire is connected with a battery, and a generator shaft is connected onto the turbine shaft at the air compressor fan end. The battery starts the oil transportation motor, the motor drives the oil pump to input kerosene in the oil tank into the shell and the nozzle spouts the ignition, the explosion gas is produced to push the turbine blade to rotate and spout the shell gas jet, the turbine blade drives the turbine shaft to rotate and drives the air compressor blade and the generator to rotate, the air compressor blade compressed air enters combustion-supporting kerosene in the shell, the electricity that the generator sent drives the oil transportation motor, at this moment, the battery cuts off the electricity that supplies the oil transportation motor, the advantage of turbine is that the output power ratio of turbine weight is bigger, the shortcoming is: 1. the ratio of the power output by the turbine to the fuel quantity consumed in 1 second is too small, namely, the fuel consumption is high, the power output is low, and is much smaller than the ratio of the power output of an internal combustion engine with the same weight to the fuel quantity consumed in 1 second, so that fuel turbines are not used on the ground in many developed countries for saving oil, and only the fuel turbines are used on tanks in the United states, the engine body is small, the space is vacated, the volume of the fuel tank is increased, the power is high, and the tanks run out quickly. 2. Turbine blades are rare earth element high temperature resistant alloy steel, which is very expensive. 3. The carbon dioxide emitted is much greater than the carbon dioxide emitted by an equivalent weight internal combustion engine. Third, it costs more than buying oil with an internal combustion engine of equal weight.

Disclosure of Invention

The invention aims to provide a main power increasing machine for increasing the negative power distance of a negative force arm of a lever by connecting cross levers in series, which has simple structure and convenient use, and various parts of the main power increasing machine have simple shapes, easy manufacture and low cost, do not burn fuel for producing carbon dioxide, do not discharge carbon dioxide, are environment-friendly and can become permanent mechanical energy of human beings.

In order to achieve the purpose, the invention adopts the following technical measures:

the technical conception is as follows: the negative force hole of the negative force arm with shorter movement stroke distance of the labor-saving lever is connected with the serial cross lever to do negative work movement, so that the stroke distance of the connecting hole of the connecting rod at the tail end of the serial cross lever doing the reciprocating negative work movement is enlarged to be longer negative work stroke distance, namely the negative work amount is increased. The connecting hole of the tail end connecting rod of the first serial crossed lever is connected and acts on the second labor-saving lever, the negative force hole of the negative force arm of the second labor-saving lever is connected and acts on the second serial crossed lever, the negative work movement stroke distance of the connecting hole of the tail end connecting rod of the second serial crossed lever is increased, the force is increased, and by analogy, the next machine is continuously connected in series, and the power increasing machine is formed.

The utility model provides a series connection is alternately lever increases active power increase machine of lever negative force arm negative force work distance, includes alternately lever, terminal connecting rod, bracing piece, presses the pinch bar, the curved lever of short, the curved lever of long, the lateral deviation shift lever, special bracing piece, the craspedodrome motor, its characterized in that: the end hole of the push-pull rod of the straight motor is connected with the main force hole of a group of short bent levers, the pull-push hole of the short bent levers is connected with the supporting hole at one end of a group of supporting rods without a gap, the supporting hole at the other end of the supporting rods is connected with the main force hole of a group of press pry rods, the supporting hole of the short bent levers is connected with the supporting hole of another group of supporting rods, the supporting hole at the other end of the other group of supporting rods is connected with the supporting hole of the press pry rods, the negative force hole of the short bent levers is connected with the force transmission hole of a group of additional crossed levers, the fulcrum hole of the additional crossed levers is connected with the fulcrum hole of the press pry rods, the fulcrum hole of the short bent lever of the first machine is arranged on the positioning hole in the machine shell, a positioning pin is inserted, the connecting hole of the tail end connecting rod of the first machine is connected with the main force hole at the end of the main force arm of the long bent lever of the second machine, the fulcrum hole of the long bent lever of the second machine is arranged on the positioning hole in the machine shell, the positioning pin is inserted, connecting the connecting hole of the end connecting rod of the second machine with the end main force hole of the main force arm of the side deviation shifting lever of the third machine, installing the supporting point hole of the side deviation shifting lever of the third machine on the positioning hole in the machine shell, inserting the positioning pin, connecting the connecting hole of the end connecting rod of the third machine with the main force hole of the end of the main force arm of the long bending lever of the fourth machine, installing the supporting point hole of the long bending lever of the fourth machine on the positioning hole in the machine shell, inserting the positioning pin, connecting the negative force hole of the large lever with the upper hole of the push rod, connecting the pull hole of the push rod with the upper hole of the pull rod, installing the supporting point holes of a group of special levers on the positioning hole in the machine shell, inserting the positioning pin, connecting the connecting hole of the end connecting rod of the first machine with the main force hole of the special lever, the negative force hole of the special lever is connected with the supporting hole at one end of the special supporting rod, the supporting hole at the other end of the special supporting rod is connected with the main force hole of the short bent lever of the second machine, and the combined holes of the holes of all the parts and the holes are inserted into the collar on the pin.

Two groups of cross levers, each group consisting of 3-10 cross levers, are selected, and are inserted alternately and vertically with their central fulcrum holes aligned with each other, and then inserted into the pins, and then clamped in the end slots of the pins by the collars, thus forming a pair of cross levers. The force transmission holes at one end of two groups of crossed levers of one pair of crossed levers are aligned and connected with the force transmission holes at one end of two groups of crossed levers of the other pair of crossed levers respectively, and the pin and the upper clamping ring are inserted. By analogy, 3-10 pairs of cross levers can be connected in series, namely a series of cross levers, also called series cross levers. Two groups of force transmission holes at one end of the string of crossed levers are respectively aligned and connected with a support hole at one end of a support rod consisting of 3-10 groups and a main force hole of a tail end connecting rod consisting of 3-10 groups, a pin and an upper clamping ring are inserted, and then the support holes at the other end of the support rod group are aligned and connected with support point holes of the tail end connecting rod group, and the clamping ring is inserted on the pin. And then the two groups of force transmission holes at the other end of the string of crossed levers are respectively aligned and connected with the negative force holes of the pressing and prying bars which are formed into a group by 3-10, and the force transmission holes at one end of the added group of crossed levers which are formed into a group by 3-10, the clamping ring is arranged on the bolt nail, the support point holes of the added group of crossed levers are aligned and connected with the support point holes of the pressing and prying bars of the group, and the clamping ring is arranged on the bolt nail, so that the added group of crossed levers and the pressing and prying bars form cross connection. The force transmission hole at the other end of the additional group of crossed levers is aligned and connected with the negative force hole at the negative force arm end of the short bent lever consisting of 3-10 groups, and a pin and an upper clamping ring are inserted. The supporting holes of the press prying bars are aligned and connected with the supporting holes at one end of the supporting rods which are formed into a group by 3-10, the supporting holes at the other end of the supporting rods are aligned and connected with the supporting holes on the negative force arm of the short bent levers, and the clamping rings are all pinned on the pins. The main force hole of the group of the press pry bars is aligned and connected with one end support hole of another group of support bars consisting of 3-10. And the other end support hole of the other group of support rods is aligned and connected with the pull-push hole on the main force arm of the group of short bent rods, and the bolts are all nailed with clamping rings. The support point holes of the group of short bent levers are aligned and connected with the positioning holes in the shell, and positioning pins are inserted. The main force hole at the main force arm end of the short bent lever is connected with the outer end hole of the push-pull rod for starting the straight-moving motor, and the pin and the upper clamping ring are inserted. The machine body suspension hole of the motor is arranged on the suspension positioning hole in the machine shell, and the positioning pin is inserted. The first series cross lever negative power distance amplifier is called the first amplifier for short. When a push-pull rod (also called a connecting rod) of the straight-moving motor performs push-pull reciprocating main power movement, a main power hole at the end of a main power arm of the short bent lever is driven to perform swing movement, a pull-push Kong Latui supporting rod on the main power arm of the short bent lever is also driven, the supporting rod pulls and pushes a main power hole of the pry rod, the press pry rod performs swing press pry movement, and when the short bent lever performs swing movement, a negative power hole at the end of a negative power arm of the short bent lever also performs swing negative power movement. The additional group cross lever is also driven to do swinging motion, so that the pinch bar and the additional group cross lever do folding and unfolding swinging motion together, the serial cross lever is also driven to do reciprocating telescopic motion, and the connecting hole of the tail end connecting rod of the serial cross lever also does reciprocating negative work motion. The more the number of the serial pairs of the serial crossed levers is, the longer the stroke distance of the reciprocating negative work movement made by the connecting hole of the tail end connecting rod is, the longer the short stroke distance of the swinging negative work movement made by the negative force hole of the negative force arm of the short bent lever is, namely the negative work amount of the reciprocating negative work movement made by the connecting hole of the tail end connecting rod is larger than the negative work amount of the swinging negative work movement made by the negative force hole of the negative force arm of the short bent lever, namely the reciprocating movement made by the connecting hole of the tail end connecting rod of the serial crossed levers is changed into the swinging negative work movement made by the negative force hole of the negative force arm of the short bent lever through the telescopic reciprocating movement of the multiple pairs of the serial crossed levers. Therefore, the long negative work stroke distance generated by the reciprocating negative work movement made by the connecting hole of the tail end connecting rod is much longer than the short stroke distance of the swinging negative work movement made by the negative force hole of the short bent lever negative force arm, and the large negative work amount generated by the small negative work amount generated by the swinging negative work movement made by the negative force hole of the short bent lever is much larger than the small negative work amount of the swinging negative work movement made by the negative force hole of the short bent lever negative force arm, and the long stroke distance and the large negative work amount of the swinging negative work movement made by the negative force hole of the short bent lever negative force arm are calculated in a phase-changing manner.

The connecting hole of the connecting rod at the tail end of the first machine is connected with the main force hole at the end of the main force arm of the long bent lever of the second machine, and the bolt is nailed with the clamping ring. The connecting hole of the connecting rod at the tail end of the second machine is connected with the main force hole at the end of the main force arm of the side deviation shift lever of the third machine, and the pin is nailed with the clamping ring. The connecting hole of the connecting rod at the tail end of the third machine is connected with the main force hole at the end head of the main force arm of the long bent lever of the fourth machine, and the bolt nails the collar. The connecting hole of the connecting rod at the tail end of the fourth machine is connected with the main force hole at the end of the main force arm of the large lever, and the bolt is nailed with the clamping ring. The negative force hole at the end of the large lever negative force arm is connected with the upper hole of the push rod, and the bolt is nailed with a clamping ring. The pull hole near the push rod upper hole is connected with the upper hole of the pull rod, and the bolt is nailed with a clamping ring. The lower hole of the push rod is connected with the push hole of the lever end of the driving right ratchet gear assembled on the driven left and right ratchet gear internal spline housing, and the plug pin is provided with a clamping ring. The lower hole of the pull rod is connected with the pull hole of the lever end of the driving left-end ratchet gear assembled on the driven left-end and right-end ratchet gear internal spline sleeves, and the bolt nails the collar. The bent lever, the fulcrum hole of the side deviation shift lever and the fulcrum hole of the big lever of each machine are all arranged on respective positioning holes in the machine shell, and positioning pins are inserted. The driving left and right ratchet gears arranged on the driven left and right ratchet gear internal spline housing are both provided with a return spring, and the driven left and right ratchet gear internal spline housing is arranged on a bearing position in the machine shell (bearing position diagram is not drawn due to public knowledge). The first machine and the second machine, the second machine and the third machine, and the third machine and the fourth machine are in opposite directions and in a reverse form relationship with each other. The active power increasing machine is used for increasing the negative power moment of the negative force arm of the lever by connecting the crossed levers in series.

The negative force hole at the end of the negative force arm of the bent lever is connected with the force transmission holes of the crossed levers at one end of one crossed lever, the next force transmission hole and the crossed lever are continuously connected in series through the force transmission hole at the other end of the crossed lever of the force transmission hole, the crossed lever belongs to the crossed lever of the bent lever pulse, and the negative force hole of the bent lever transmits force to the crossed lever of the wire pulse connected in series with the negative force hole of the bent lever. The cross lever of the other line pulse can not obtain the transmission force in a free state. The force transmission hole at one end of the cross lever of the other line pulse is connected with the negative force hole of the press pry bar, the main force hole of the press pry bar is connected with one end of a group of support bars, the other end of each support bar is connected with the pulling and pushing hole on the main force arm of the bent lever, the power of the main force arm of the bent lever is transmitted to the support bars and the press pry bar, the press pry bar transmits the force to the cross lever of the other line pulse through swinging motion, and the cross lever of the other line pulse belongs to the press pry bar pulse cross lever. The distance from the supporting hole center of the pressing prying rod to the hole center of the main force is equal to the distance from the hole centers of the two ends of the supporting rod, and the distance from the supporting hole centers of all the bent levers and the lateral offset shifting levers to the pulling and pushing hole centers is equal.

The connection hole of the end connecting rod of the first machine is connected with the main force hole at one end of a special lever which is composed of 3-10 groups, the bolt is nailed with a clamping ring, the support hole at the other end of the special lever is installed on the positioning hole in the shell, the positioning pin is inserted, the negative force hole at the middle section of the special lever is connected with the support hole at one end of a special supporting rod which is composed of 3-10 groups, the bolt is nailed with a clamping ring, the support hole at the other end of the special supporting lever is connected with the main force hole at the end of the main force arm of the short bent lever of the second machine, the pin is inserted and the clamping ring is installed.

And (3) assembling, assembling and maintaining the active power increasing machine with the series-connection crossed lever and the negative force power moment of the increasing lever negative force arm, and preventing and avoiding hand clamping.

The negative force hole of the negative force arm with shorter swinging negative work motion stroke distance of the labor-saving lever is connected with and acts on the serial cross lever to perform telescopic negative work motion, so that the stroke distance of the connecting hole of the tail end connecting rod of the serial cross lever to perform reciprocating negative work motion is enlarged into a longer reciprocating negative work motion stroke distance, namely, the large negative work amount performed by the connecting hole of the tail end connecting rod is enlarged, and the main power of the main power source straight-moving motor are increased by phase change. The power of the main power for starting the terminal is small, and the power output by the terminal is increased by many times.

The invention is characterized in that when the negative force hole of the shorter negative force arm of the bending lever does swinging negative work movement, the negative work distance is shorter, but the negative force hole drives a plurality of pairs of serial crossed levers to do negative work telescopic movement, so that the stroke distance of the reciprocating negative work movement made by the connecting hole of the connecting rod at the tail end of the serial crossed levers is more and more longer than the stroke distance of the negative work swinging movement made by the negative force hole of the negative force arm of the bending lever. If the connecting hole of the tail end connecting rod drives a proper large negative force, the negative work amount of the connecting hole is larger than that of the negative force hole of the negative force arm of the bent lever and is also larger than the main work amount of the main force source straight motor, conversely, the main force work of the main force source straight motor is increased in a phase-changing manner, and the power of the main force source straight motor is increased by dividing the work time. A plurality of units are connected in series, so that the output power of the tail end unit is far greater than the main power of the main power source straight-moving motor. If a generator with larger power is driven, and the electricity of the generator is returned to a small part of electricity to supply the main force source to the straight-going motor, the invention breaks through the James Joule energy conservation law.

The technical problems and difficulties solved by the invention are as follows: the invention utilizes the serially-connected crossed levers to do reciprocating and stretching negative work movement, increases the negative work distance of swinging negative work movement made by the negative force hole of the negative force arm of the bent lever in a phase-changing manner, increases the negative work amount, and increases the output power by dividing the work time; difficulty is as follows: the invention uses the series cross lever technology to increase the negative work distance of the negative force hole of the negative force arm of the bent lever in a phase-changing way, and increases the negative work amount, thereby overcoming the negative force or negative work which is much larger than the main force or main work of the main force source straight-moving motor. The technical effect achieved by the invention is that the power for starting the straight-going motor is small, and the output power is large. The invention has the advantages of no petroleum, no external electricity, no coal and no nuclear fission material, saves economy and does not discharge carbon dioxide. The technical scheme of the invention is that the power consumption is less, and the output power is larger than the power consumption. The prior art uses a plurality of energy sources to generate large power, and the working efficiency is low.

The invention relates to a proportional quantity calculation formula of the negative work distance of reciprocating negative work movement made by a connecting hole of a tail end connecting rod connected with a series cross lever and the negative work distance of swinging negative work movement made by the negative force hole of a lever negative force arm, wherein the swinging negative work movement made by the negative force hole of the lever negative force arm acts on reciprocating telescopic negative work movement made by the connected series cross lever: the distance between the supporting hole center of the short bent lever and the negative force hole center, the distance between the supporting hole centers at two ends of the supporting rod, the distance between the supporting hole center of the pressing lever and the fulcrum hole center, the distance between the fulcrum hole center of the pressing lever and the negative force hole center, and the distance between the force transmission hole center of the crossed lever and the fulcrum hole center are all equal, R is set as a representative sign, and when a straight-moving motor push-pull rod is arranged to push and pull the main force hole of the short bent lever, the short bent lever does 32-degree swing motion. When the two crossed lever sets of each pair of crossed levers connected in series are in a vertical state (for example, as shown in fig. 32), the distance from the supporting hole center of the short bent lever to the fulcrum hole center of the press lever is 1.414R. When the push-pull rod of the straight-going motor does telescopic motion, the short bent lever is also pushed and pulled to do 32-degree swinging motion, two crossed lever groups of each pair of crossed levers of the series-connected crossed levers are also driven to be mutually vertically opened to be closed and folded (as shown in figure 33), and each crossed lever does 32-degree swinging motion. Then the negative work distance of the negative force hole center of the short bending lever doing the 32 ° swinging negative work motion is 2R pi × 32 °/360 ° =2R × 3.14 × 0.0888=0.557664r. When the push-pull rod of the straight motor extends out, the short bent lever is pushed to swing, two groups of crossed levers of each pair of crossed levers are also driven to be folded from a vertical opening state (for example, figure 33), and the distance from the supporting hole center of the short bent lever to the fulcrum hole center of the press pry rod is set as X. When the push-pull rod of the straight motor retracts, the short bent lever is pulled to swing, two groups of crossed levers of each pair of crossed levers are driven to be folded to be vertically unfolded, and the distance from the supporting hole center of the short bent lever to the fulcrum hole center of the press prying rod is set to be Y, then con 45-32 degrees =1/2X ÷ R =0.9744,1/2X =0.9744R, and X = 2X 0.9744R =1.9488R. con45 ° =1/2Y ÷ R =0.7071,1/2y =0.7071r, Y =2 × 0.7071r =1.4142r. When the negative force hole center of the short bending lever does swing motion at 32 degrees, the negative work motion distance which is repeated back and forth is 1/2X-1/2Y =0.9744R-0.7071R =0.2673R. The distance of the reciprocating negative work movement of the fulcrum hole center of the prying bar is X-Y =1.9488R-1.4142R =0.5346R. The negative power distance 0.557664R is that the negative force hole close to the short bent lever does 32-degree swinging negative power motion. Then the distance of the back and forth movement of the support point hole of the first pair of crossed levers is 2 × 0.5346r =1.0692r, which exceeds the distance of the back movement of the back force hole of the short bent lever making 32 ° swinging back and forth movement of the back force hole of the short bent lever 0.557664R, which is the first bright light of the mechanical energy of the new human serial crossed lever. Then the center of the fulcrum hole of the second pair of crossed levers is extended and contracted to restore the negative power movement distance to 3 × 0.5346r =1.6038r. The distance of the third pair of crossed levers for the movement of the third pair of crossed levers for the negative work by stretching and retracting the fulcrum hole center is 4 multiplied by 0.5346r =2.1384r. The movement distance of the fulcrum hole center of the tail end connecting rod for the recovery of negative work by stretching is 5 multiplied by 0.5346R =2.673R.2.673 ÷ 0.557664 ≈ 4.79. According to the invention, the pivot hole center of the tail end connecting rod of the first machine is phase-shifted to increase the main power of the straight motor by 4.79 times, and the second machine, the third machine and the fourth machine are connected in series, so that the main power of the straight motor is phase-shifted to increase by 4 x 4.79=19.16 times by the connecting hole center of the tail end connecting rod of the fourth machine.

Compared with the prior art, the invention has the following advantages and effects:

compared with the internal combustion engine, after the piston of the internal combustion engine generates the power of one stroke, three quarters of time is consumed unnecessarily to not generate the power, and the internal combustion engine of the automobile has a plurality of reports of spontaneous combustion fire disasters without signs because gasoline is needed. The invention has no unnecessary time consumption, no fuel oil and no fire source. Compared with a motor, the invention has the following advantages: the power generated by the electricity consumed by the motor is limited, the consumed electric quantity is small, and the increased power is nearly 20 times. Compared with a coal-fired power machine, the inner wall of the pot of the coal-fired power machine is used for a long time, calcium carbonate dirt is easy to generate, the heat conductivity of the calcium carbonate is low, the heat conversion power rate is easy to reduce, and the water vapor and the power are reduced. In addition, the coal burning machine needs to carry a large amount of coal and is also provided with a water injection machine with high power, and the volume and the weight of the whole coal burning machine are very heavy. The invention does not need coal and fuel tank, and is light in weight. Compared with a nuclear power machine, the invention does not need a complex high-tech technology with excessive high cost like the nuclear power machine, does not need to consume excessive rare earth elements meaninglessly, does not need a nuclear reactor shell made of nearly thousand tons of high-grade stainless steel smelted by expensive rare earth elements, and does not need nuclear reaction fission materials. The invention does not need to continuously spend money on buying fuel oil, buying electricity, buying coal and buying nuclear fission materials. The invention has the advantages of small used electric power, large output power and large overcome negative force.

The invention has the advantages of less energy consumption, large output power and high working efficiency. The main power increasing machine has the advantages of simple structure, convenient use, simple shapes of various parts, easy manufacture and low cost, and can produce all thin parts only by one laser cutting machine, one low-temperature laser quenching machine, one punch press and one small drill press. The cutting and the punching and the quenching are carried out, and a small workshop can become the production plant of the invention. That is, the production of the housing is somewhat difficult and requires tens or hundreds of pairs of cast steel molds. The fuel for producing carbon dioxide is not burnt, carbon dioxide is not discharged, the environment is protected, and the effect can become permanent mechanical energy of human beings.

Drawings

Fig. 1 is a schematic structural diagram of a cross lever of a main power increasing machine for increasing negative power moment of a negative force arm of a lever which is connected in series with the cross lever (the cross lever is a first main part of the invention).

Fig. 2 is a top view of fig. 1.

Fig. 3 is a schematic structural diagram of a tail end connecting rod of a main power increasing machine for increasing the negative power moment of a negative force arm of a lever through serially connecting crossed levers.

Fig. 4 is a top view of fig. 3.

Fig. 5 is a schematic structural diagram of a support rod of a main power increasing machine for increasing the negative power moment of a negative force arm of a lever through serially connecting crossed levers.

Fig. 6 is a top view of fig. 5.

Fig. 7 is a schematic structural diagram of a press pry bar of a main power increasing machine for increasing the negative power moment of a negative force arm of a lever through serially connecting crossed levers.

Fig. 8 is a top view of fig. 7.

Fig. 9 is a schematic structural diagram of a short bent lever of a main power increasing machine for increasing the negative power moment of a negative force arm of a series-connection crossed lever.

Fig. 10 is a top view of fig. 9.

Fig. 11 is a schematic structural diagram of a long bent lever of a main power increasing machine for increasing the negative power moment of a negative force arm of a series-connection crossed lever.

Fig. 12 is a top view of fig. 11.

Fig. 13 is a schematic structural diagram of a main power increasing machine side offset lever for increasing the negative power moment of the negative force arm of the lever with crossed levers connected in series.

Fig. 14 is a top view of fig. 13.

Fig. 15 is a schematic structural diagram of a lever dedicated for a main power booster for increasing the negative power moment of the negative arm of the lever by connecting cross levers in series.

Fig. 16 is a left side view of fig. 15.

Fig. 17 is a schematic structural diagram of a supporting rod dedicated for a main power booster for increasing the negative power moment of a negative force arm of a lever by connecting cross levers in series.

Fig. 18 is a left side view of fig. 17.

Fig. 19 is a schematic structural diagram of a main power increasing lever for increasing the negative power moment of the negative arm of the lever with the cross levers connected in series.

Fig. 20 is a top view of fig. 19.

Fig. 21 is a schematic structural diagram of a push rod of a main power increasing machine for increasing the negative power moment of a negative force arm of a lever through serially-connected crossed levers.

Fig. 22 is a drawing a of fig. 21.

Fig. 23 is a schematic structural diagram of a pull rod of a main power increasing machine for increasing the negative power moment of a negative force arm of a lever through serially-connected crossed levers.

Fig. 24 is a top view of fig. 23.

Fig. 25 is a schematic structural diagram of a driving left-end ratchet gear of a driving power increasing machine for increasing the negative power moment of a negative force arm of a lever by connecting cross levers in series.

Fig. 26 is a left side view of fig. 25.

Fig. 27 is a schematic structural diagram of the active power increasing machine active right ratchet gear of the negative force moment of the negative force arm of the series-connection cross lever increasing lever.

FIG. 28 is a schematic structural view of the driven left and right ratchet gear internal spline housing of the main power increasing machine with the series-connection cross lever increasing lever negative force moment.

Fig. 29 is a schematic structural view showing that the driving left-end ratchet gear and the driving right-end ratchet gear are respectively assembled on the left and right ends of the left and right ratchet wheel position on the driven left-end and right-end ratchet gear internal spline housing from the left and right, and the respective return springs of the driving left-end ratchet gear and the driving right-end ratchet gear are respectively assembled on the left and right.

FIG. 30 is a schematic view showing a structure in which 3 to 10 crossing levers are selected to form a set of crossing levers, the two sets of crossing levers are alternately inserted one after another, aligned with and perpendicularly connected to each other through intermediate fulcrum holes, a pin is inserted into the intermediate fulcrum holes, and a collar is mounted on a ring groove at the tail end of the pin.

Fig. 31 is a left side view of fig. 30, which is called a cross lever.

Fig. 32 shows a series of cross levers connected in series by a plurality of pairs of cross levers connected to each other through force transmission holes, two force transmission holes of one end of the series of cross levers are respectively connected to main force holes of a group of end links and support holes of one end of a group of support rods, and support holes of the group of end links are connected to support holes of the other end of the group of support rods. The two force transmission holes at the other end of the serial cross lever are respectively connected with the negative force holes of a group of press pry bars and the force transmission holes of a group of additional cross levers. The fulcrum hole of the group of press pry bars is connected with the fulcrum hole of the additional group of cross levers, and the force transmission hole at the other end of the additional group of cross levers is connected with the negative force hole of the group of short bent levers. The supporting hole of the group of pressing pry bars is connected with the supporting hole at one end of the group of supporting bars, the supporting hole at the other end of the group of supporting bars is connected with the supporting hole of the group of short bent levers, the main force hole of the group of pressing pry bars is connected with the supporting hole at one end of the other group of supporting bars, the supporting hole at the other end of the other group of supporting bars is connected with the pulling and pushing hole of the group of short bent levers, and the connecting holes are all inserted with pins and an upper clamping ring. The support point hole of the short bent lever is installed and connected on the positioning hole in the machine shell, and the positioning pin is inserted. The main force hole of the short bent lever is connected with the outer end hole of the push-pull rod of the straight-moving motor, and the pin and the upper retainer ring are inserted. The hanging hole of the straight-moving motor body is arranged on the positioning hole in the shell, and the like. The two machines are combined into a series cross lever negative power distance amplification machine, which is called a first machine for short.

Fig. 33 is a schematic view of the first machine with the tandem cross levers extended from the retracted configuration of fig. 32 to fig. 33 with the straight motor push-pull rod pushed outward.

Fig. 34 is a schematic view of fig. 32 and 33 in the direction of C. The section view of the hole ring of the hanging hole of the straight-moving motor body of fig. 32 and 33, which is installed in the positioning hole in the casing, is a schematic view from direction D of fig. 34.

Fig. 35 shows the connection of the end link of the first machine with the main force aperture of the main force arm of the long bent lever of the second machine, with the latch pin attached to the collar. The support point hole of the long bending lever of the second machine is arranged on the positioning hole in the machine shell, and the positioning pin is inserted. The connecting hole of the connecting rod at the tail end of the second machine is connected with the main force hole of the main force arm of the lateral offset shift lever of the third machine, and the pin is nailed with the clamping ring. (to avoid obstructing the view of the first machine, and to avoid drawing a third machine parallel to the first machine side and on the back of the first machine), the first machine and the second machine are opposite in direction and are in reverse form relationship with each other.

FIG. 36 shows the connecting hole of the end link of the third machine connected to the main force hole of the main force arm of the long bent lever of the fourth machine, with the latch pin attached to the collar. The connecting hole of the connecting rod at the tail end of the fourth machine is connected with the main force hole of the main force arm of the large lever, and the bolt is nailed with the clamping ring. The fulcrum hole of the lateral deviation shifting lever of the third machine, the fulcrum hole of the long bending lever of the fourth machine and the fulcrum hole of the large lever are respectively arranged on respective positioning holes in the machine shell, and positioning pins are inserted. The third machine and the fourth machine are in reverse directions and are in reverse form.

FIG. 37 is a schematic view showing the displacement state of a set of laterally offset levers formed by connecting laterally offset levers of a plurality of third machines in parallel, the upper part of the main arm and the second machine are the E-direction view of FIG. 35, the lower part of the main arm has a fulcrum hole at the root and a negative arm, and the third machines are the F-direction view of FIG. 36

FIG. 38 shows the connection of the negative force hole at the end of the large lever negative force arm installed in the positioning hole in the case with the upper hole of the push rod, and the latch pin is attached to the collar. The pull hole of the push rod is connected with the upper hole of the pull rod, and the bolt nails the collar. The lower hole of the push rod is connected with the push hole of the driving right ratchet gear lever in the B-direction drawing of figure 29, and the latch nail is provided with a collar. The lower hole of the pull rod is connected with the pull hole of the driving left end ratchet gear lever in the B-direction of figure 29, and the bolt nail is provided with a collar.

FIG. 39 shows the connection hole of the end link of the first machine and the main force hole of one end of the special lever composed of 3-10 groups, the bolt is nailed with a collar, and the fulcrum hole of the other end of the special lever is installed on the positioning hole in the machine shell, and the positioning pin is inserted. The negative force hole in the middle of the special lever is connected with the supporting hole at one end of the special supporting rod which is composed of 3-10 groups, and the bolt is nailed with a clamping ring. The supporting hole at the other end of the special supporting rod is connected with the main force hole at the end of the main force arm of the short bent lever of the second machine to form a schematic diagram of the special machine.

Detailed Description

Example 1:

as can be seen from fig. 1, 2, 3, 4, 5, and 6, a main power amplifier for increasing negative power moment of negative arm of lever by serially connecting crossed levers includes a crossed lever 1, a terminal connecting rod 2, a supporting rod 3, a prying rod 4, a short bending lever 5, a long bending lever 6, a lateral offset shifting lever 7, a special lever 8, a special supporting rod 9, and a matched straight-moving motor 21, and is characterized in that: the end hole 21.2 of the push-pull rod of the straight motor 21 is connected with the main force hole 5.3 of the group of short bent levers 5 which are connected in parallel, the pull-push hole 5.7 of the short bent lever 5 which is connected in parallel is connected with the one end support hole 3.1 of the group of support rods 3 which are connected in parallel and have no edge 3.3, the other end support hole 3.1 of the support rod 3 is connected with the main force hole 4.5 of the group of press pry rods 4 which are connected in parallel, and the number of the support holes at the two ends of the support rod 3 which are connected with the pull-push hole 5.7 of the short bent lever 5 and the main force hole 4.5 of the press pry rod 4 is 3.1 because the edge 3.3 is not required to be opened in the support holes at the two ends of the support rod 3 which is connected with the pull-push hole 5.7 of the short bent lever 5 and the main force hole 4.5 of the press pry rod 4. The support hole 5.6 of the short bending lever 5 connected in parallel is connected with the support hole 3.1 of the support rod 3 connected in parallel, and the support hole 3.2 at the other end of the support rod 3 is connected with the support hole 4.6 of the press pry rod 4 connected in parallel. The negative force hole 5.4 of the short bending lever 5 which is connected in parallel is connected with the force transmission hole 1.2 of the group of the additional group cross levers 1 which are connected in parallel, and the fulcrum hole 1.3 of the group of the additional group cross levers 1 which are connected in parallel is connected with the fulcrum hole 4.8 of the pressure pry bar 4. One group of parallel crossed levers 1 and the other group of parallel crossed levers 1 are alternately inserted into each other, and the branch point holes 1.3 of the two groups of parallel crossed levers 1 are aligned and connected, inserted into a pin 18, and clamped on an annular groove at the tail end of the pin by a clamping ring 19. The two groups of crossed levers 1 are mutually perpendicularly crossed, so that a pair of crossed levers 17 is formed, the number of one group of parallel crossed levers 1 is changed from 1 to 17.1, the number of the other group of crossed levers 1 is changed from 1 to 17.2, and other numbers are not changed. The force transmission holes 1.2 of one group of crossed levers 17.1 of a first pair of crossed levers 17 are connected with the force transmission holes 1.2 of the other group of crossed levers 17.2 of a second pair of crossed levers 17, the force transmission holes 1.2 of the other group of crossed levers 17.2 of the first pair of crossed levers 17 are connected with the force transmission holes 1.2 of one group of crossed levers 17.1 of the second pair of crossed levers 17, and so on, a plurality of pairs (3-10) of crossed levers 17 are connected in series to form a series of crossed levers 20 which are also called as series crossed levers 20, and then two force transmission holes 1.2 at one end of the series of crossed levers 20 are respectively connected with the other force transmission hole 1.2 of the added group of crossed levers 1 and the negative force hole 4.7 of the pinch bar 4, two force transmission holes 1.2 at the other end of the string of crossed levers 20 are respectively connected with a group of main force holes 2.1 of the end connecting rods 2 connected in parallel and a group of supporting holes 3.2 of the supporting rods 3 connected in parallel, fulcrum holes 2.2 of the end connecting rods 2 are connected with the supporting holes 3.1 of the supporting rods 3, pins 18 and upper clamping rings 19 are inserted into combined holes of all the holes and the holes, namely a first serial crossed lever negative force power amplifier of the main force power amplifier for increasing the negative force power of the negative force arm of the lever is connected in series, namely a first machine 23 for short, a fulcrum hole 5.5 of a short bent lever 5 of the first machine 23 is installed on a positioning hole 22.1 of a machine shell 22, and a positioning pin 24 is inserted.

Fig. 1 is a cross lever 1 which is a first main part of the invention, a rod with equal length at two end sections is a force arm 1.1, holes at two ends are force transmission holes 1.2, a fulcrum hole 1.3 is arranged in the middle, and the force transmission holes 1.2 at two ends are provided with edges 1.4 to prevent adjacent parts from colliding. Fig. 2 is a top view of fig. 1, and as seen from fig. 2, the cross lever is flat and thin. Fig. 3 shows a terminal connecting rod 2, which is called a terminal rod for short, one end of the terminal connecting rod is a main force hole 2.1, an inner section hole is a fulcrum hole 2.2, the other end of the terminal connecting rod is a connecting hole 2.3, the main force hole 2.1 is provided with a gap 2.4, fig. 4 is a top view of fig. 3, and fig. 4 shows that the terminal connecting rod 2 is flat and thin.

Fig. 5 shows the support bar 3, the two ends are support holes 3.1 and 3.2, the support hole 3.2 has a notch 3.3. Fig. 6 is a top view of fig. 5. Fig. 6 shows that the support rod 3 is flat and thin. Fig. 7 shows that the press pry bar 4,4.1 and 4.2 are combined bending main force arms, 4.3 is a reinforcing rib supporting the 4.1 and 4.2 combined bending main force arms, 4.4 is a negative force arm, the end of the main force arm 4.2 is a main force hole 4.5, a supporting hole 4.6 is arranged between the combined bending main force arms 4.1 and 4.2, the end of the negative force arm 4.4 is a negative force hole 4.7, a fulcrum hole 4.8 is arranged between the main force arm 4.1 and the negative force arm 4.4, the supporting hole 4.6 is provided with a notch 4.9, and the negative force hole 4.7 is provided with a notch 4.10. Fig. 8 is a plan view of fig. 7, and the press lever 4 is flat and thin.

Fig. 9 shows that the short bent lever 5,5.1 is a main force arm, 5.2 is a negative force arm, 5.3 is a main force hole at the end of the main force arm 5.1, 5.4 is a negative force hole at the end of the negative force arm 5.2, 5.5 is a fulcrum hole, 5.6 is a support hole located on the negative force arm 5.2, the support hole 5.6 can also be used as a fulcrum hole, 5.7 is a pulling and pushing hole located on the main force arm 5.1, and the negative force hole 5.4 has a notch 5.8. Fig. 10 is a plan view of fig. 9, and the short bent lever 5 is flat and thin.

Fig. 11 shows that the long bending lever 6,6.1 is a main force arm, 6.2 is a negative force arm, 6.3 is a main force hole at the end of the main force arm 6.1, 6.4 is a negative force hole at the end of the negative force arm 6.2, 6.5 is a fulcrum hole, 6.6 is a support hole located on the negative force arm 6.2, the support hole 6.6 can also be used as a fulcrum hole, 6.7 is a pulling and pushing hole located on the main force arm 6.1, and the negative force hole 6.4 is provided with a notch edge 6.8. Fig. 12 is a plan view of fig. 11, and the long bending lever 6 is flat and thin.

Fig. 13 shows that the lateral deviation shift lever 7,7.1 is a main force arm, 7.2 is a negative force arm, 7.3 is a main force hole at the end of the main force arm 7.1, 7.4 is a negative force hole at the end of the negative force arm 7.2, 7.5 is a fulcrum hole, 7.6 is a support hole located on the negative force arm 7.2, the support hole 7.6 can also be used as a fulcrum hole, 7.7 is a pulling and pushing hole located on the main force arm 7.1, and the negative force hole 7.4 is provided with a notch 7.8. Fig. 14 is a plan view of fig. 13, the side shift lever 7 is flat and thin, and as can be seen from fig. 14, the main force arm 7.1 of the side shift lever 7 is in a side shift shape.

Fig. 15 is a special lever 8, the whole lever is a main force arm represented by 8.1, 8.2 is a negative force arm, 8.3 is a main force hole, 8.4 is a negative force hole, 8.5 is a fulcrum hole, namely, the part from the hole center of the negative force hole 8.4 to the hole center of the fulcrum hole 8.5 is the negative force arm 8.2, and the whole section from the hole center of the main force hole 8.3 to the hole center of the fulcrum hole 8.5 is the main force arm 8.1. Fig. 16 is a left side view of fig. 15, and fig. 16 shows that the dedicated lever 8 is flat and thin.

Fig. 17 shows the dedicated support bar 9, and the support holes 9.1 are formed at both ends of the dedicated support bar 9. Fig. 18 is a left side view of fig. 17, and the exclusive stay 9 is flat and thin.

Fig. 19 shows a large lever 10, 10.1 a main force arm, 10.2 a negative force arm, 10.3 a main force hole, 10.4 a negative force hole, and 10.5 a fulcrum hole. Fig. 20 is a top view of fig. 19. As can be seen in fig. 20, the main force aperture 10.3 is multi-pronged and the negative force aperture 10.4 is two-pronged.

Fig. 21 shows the push rod 11, 11.1 the upper hole, 11.2 the lower hole, 11.3 the pull hole. Fig. 22 is a view a of fig. 21, and it can be seen from fig. 22 that the lower hole 11.2 is bifurcated and the pull hole 11.3 is bifurcated.

Fig. 23 shows the tie rod 12, 12.1 the upper hole and 12.2 the lower hole. Fig. 24 is a top view of fig. 23, and as can be seen in fig. 24, the lower aperture 12.2 is bifurcated.

Fig. 25 shows the driving left ratchet wheel 13, in fig. 25, the reference numeral 13.1 is the driving left ratchet, 13.2 is the lever of the driving left ratchet wheel 13, 13.3 is the pull hole of the end of the lever 13.2 of the driving left ratchet wheel 13, and 13.4 is the positioning hole of the driving left ratchet wheel 13. Fig. 26 is a left side view of fig. 25, and reference numeral 13.5 in fig. 26 is a stabilizing sleeve for the capture hole 13.4 of the driving left end ratchet-gear 13. Fig. 27 is a side view of the driving right ratchet gear 14, in fig. 27, reference numeral 14.1 is a stable sleeve of the driving right ratchet, 14.2 is a lever of the driving right ratchet gear 14, 14.3 is a push hole of the end of the lever 14.2 of the driving right ratchet gear 14, 14.4 is a positioning hole (dotted line) of the driving right ratchet gear 14, and 14.5 is a positioning hole 14.4 of the driving right ratchet gear 14. Fig. 28 shows the driven left and right ratchet gear internally splined hub 15, in which reference numeral 15.1 is the driven left end ratchet of the driven left and right ratchet gear internally splined hub 15, 15.2 is the driven right end ratchet, 15.3 is the left internally splined hub of the driven left and right ratchet gear internally splined hub 15, 15.4 is the right internally splined hub, and 15.5 is the internal spline (four horizontal dotted lines) of the driven left and right ratchet gear internally splined hub 15. Fig. 29 shows that the positioning hole 13.4 (no reference numeral in the figure) of the driving left-end ratchet gear 13 is sleeved on the left internal spline housing 15.3 of the internal spline housing 15 of the driven left-end and right-end ratchet gears, and the return spring 16 of the driving left-end ratchet gear 13 is further installed, so that the driving left-end ratchet 13.1 of the driving left-end ratchet gear 13 is meshed with the driven left-end ratchet 15.1 of the driven left-end and right-end ratchet gear internal spline housing 15. The positioning hole 14.4 (no reference number in the figure) of the driving right-end ratchet gear 14 is sleeved on the right inner spline housing 15.4 of the driven left-end and right-end ratchet gear inner spline housing 15, and the return spring 16 of the driving right-end ratchet gear 14 is arranged, so that the driving right-end ratchet 14.1 of the driving right-end ratchet gear 14 is meshed with the driven right-end ratchet 15.2 of the driven left-end and right-end ratchet gear inner spline housing 15.

Fig. 30 and its left view fig. 31 show a pair of cross levers 17, which is formed by selecting 3-10 cross levers 1 to form a first set of cross levers 17.1, selecting 3-10 cross levers 1 to form a second set of cross levers 17.2, the two sets of cross levers 17.1 and 17.2 are alternately vertically inserted and arranged with each other, aligned with the middle fulcrum hole 1.3, inserted into the pin 18, and clamped with the collar 19 on the tail slot of the pin 18, and the two sets of cross levers 17.1 and 17.2 are vertically arranged with each other, which is the pair of cross levers 17.

In fig. 32, the 3-10 pairs of crossing levers 17 are connected in series, specifically, a force transmission hole 1.2 at one end of a first group of crossing levers 17.1 of the first pair of crossing levers 17 is aligned and connected with a force transmission hole 1.2 at one end of a second group of crossing levers 17.2 of the second pair of crossing levers 17, a latch pin 18 and an upper collar 19 are connected in series, and then a force transmission hole 1.2 at one end of the second group of crossing levers 17.2 of the first pair of crossing levers 17 is aligned and connected with a force transmission hole 1.2 at one end of the first group of crossing levers 17.1 of the second pair of crossing levers 17, a latch pin 18 and an upper collar 19 are connected. In the same way, 3-10 pairs of cross levers 17 are connected in series, and the cross levers are a series of cross levers 20 which are also called series cross levers. Connecting one end force transmission hole 1.2 of the string of crossed levers 20 with a main force hole 2.1 of a group of end connecting rods 2 formed by connecting 3-10 end connecting rods 2 in parallel, connecting a clamping ring 19 on a bolt pin 18, connecting the other end force transmission hole 1.2 with a supporting hole 3.2 of one end of a group of supporting rods 3 formed by connecting 3-10 support rods 3 in parallel, connecting the other end supporting hole 3.1 of the supporting rod 3 with a supporting point hole 2.2 of the end connecting rod 2, connecting one end force transmission hole 1.2 of the string of crossed levers 20 with a negative force hole 4.7 of a group of pressure prying rods 4 formed by connecting 3-10 support rods in parallel, connecting the other end force transmission hole 1.2 with a force transmission hole 1.2 of a group of crossed levers 1 formed by connecting 3-10 crossed levers 1, connecting a clamping ring 19 on the bolt pin 18, connecting a supporting point hole 4.8 of the pressure prying rods 4 with a supporting point hole 1.3 of the group of crossed levers 1, a clamping ring 19 is arranged on a bolt pin 18, a force transmission hole 1.2 at the other end of the additional group of crossed levers 1 is connected with a negative force hole 5.4 of a short bent lever 5 which is formed into a group by 3-10 in parallel, the clamping ring 19 is arranged on the bolt pin 18, a support hole 4.6 of a press pry bar 4 is connected with a support hole 3.2 of a support bar 3 which is formed into a group by 3-10, a support hole 3.1 at the other end of the support bar 3 is connected with a support hole 5.6 of the short bent lever 5, the clamping ring 19 is arranged on the bolt pin 18, a main force hole 4.5 of the press pry bar 4 is connected with a support hole 3.1 at one end of another support bar 3 which is formed into a group by 3-10 in parallel, the support hole 3.1 at the other end of the support bar 3 is connected with a pull-push hole 5.7 of the short bent lever 5, the clamping ring 19 is arranged on the bolt pin 18, and the support bar does not need to open the support holes 3.7 at the two ends of the support bar 3 connected with the pull-push hole 5 of the short bent lever 5 and the press pry bar 4.5, the number of the supporting holes at both ends of the supporting bar 3 connected with the pulling and pushing hole 5.7 of the short bending lever 5 and the main force hole 4.5 of the press lever 4 is set to be 3.1. The main force hole 5.3 of the short bent lever 5 is connected with the outer end hole 21.2 of the push-pull rod 21.1 of the starting straight-moving motor 21, and the plug pin 18 is provided with a clamping ring 19, so that the series cross lever negative force power distance amplifier 23 is called a first machine for short. Then, a fulcrum hole 5.5 of the short bent lever 5 of the first machine is arranged on a positioning hole 22.1 in the machine shell 22, a positioning pin 24 is inserted, a hanging hole 21.3 of the motor 21 is arranged on a hanging positioning hole 22.2 in the machine shell 22, the positioning pin 24 is inserted, and the section oblique line is a hole ring 22.3 of the positioning hole 22.2 of the machine shell 22.

Fig. 33 is a functional effect diagram of fig. 32, when the push-pull rod 21.1 of the motor 21 is retracted in fig. 32, the first set of intersecting levers 17.1 and the second set of intersecting levers 17.2 of each pair of intersecting levers 17 of the series of intersecting levers 20 are in an open vertical state, so that the series of intersecting levers 20 are in a retracted state, and when fig. 33 is reached, the push-pull rod 21.1 of the motor 21 is extended to push the short bending lever 5 to perform a swinging motion, and the short bending lever 5 also drives the press pry bar 4 and the additional intersecting lever 1 to perform a swinging motion, so that the press pry bar 4 and the additional intersecting lever 1 are in an open state to a closed state, and also drives the series of intersecting levers 20 to perform an extended state from a retracted state to perform a repeated negative work motion, see fig. 33. Taking fig. 32 and 33 for comparison, the distance of the telescopic negative work movement from the connecting hole 2.3 in fig. 32 to the connecting hole 2.3 in fig. 33 is very long, and is longer than the distance of the swinging negative work movement from the negative force hole 5.4 of the short bent lever 5. The more the pairs of the crossed levers 17 are connected in series, the longer the range of the motion distance of the telescopic reciprocating negative work made by the connecting hole 2.3 is, namely, the larger the negative work made by the connecting hole 2.3 is, namely, the action of the telescopic negative work made by the multiple pairs of crossed levers 17 connected in series makes the larger negative work made by the connecting hole 2.3 replace the smaller negative work made by the negative hole 5.4 of the short bent lever 5 in a phase-changing manner. If the larger negative power work done by the connecting hole 2.3 is divided by the time of doing the negative power work, the negative power done by the connecting hole 2.3 is also large, that is, the series cross lever negative power distance amplifier 23 becomes a power amplifier of the straight-moving motor 21 in a phase-changing manner.

Fig. 34 is a C-view of fig. 32 and 33, and a hole ring 22.3 (shown in a cross-sectional oblique view) of a suspension positioning hole 22.2 of the in-line motor 21 in the housing 22 of fig. 32 and 33 is a D-view of fig. 34. The position 22.2 in fig. 34 is a suspension positioning hole (shown by a dotted line) of the linear motor 21, 22.3 is a hole ring of the suspension positioning hole 22.2 of the linear motor 21 in the housing 22, and 22.4 is a support member of the hole ring 22.3 of the suspension positioning hole 22.2 of the linear motor 21 in the housing 22.

Fig. 35 shows that the connecting hole 2.3 of the end link 2 of the first machine 23 is connected with the main force hole 6.3 of the end of the main force arm 6.1 of the long bent lever 6 of the second machine 25, the bolt pin 18 and the upper clamp ring 19 are used for installing the fulcrum hole 6.5 of the long bent lever 6 of the second machine 25 on the positioning hole 22.5 in the casing 22, the positioning pin 24 is inserted, the connecting hole 2.3 of the end link 2 of the second machine 25 is connected with the end main force hole 7.3 of the main force arm 7.1 of the lateral deviation shifting lever 7 of the third machine, and the clamp ring 19 is arranged on the bolt pin 18. It can be seen from figure 35 that the extension and retraction of the cross bar 20 of the first machine 23 and the cross bar 20 of the second machine 25 are in opposite directions and that the machines are in inverted relationship to each other.

Fig. 36 shows the connection hole 2.3 of the end link 2 of the third machine 26 and the main force hole 6.3 of the end of the main force arm 6.1 of the long bent lever 6 of the fourth machine 27, the pin 18 (18 in the figure indicates the pin head), the connection hole 2.3 of the end link 2 of the fourth machine 27 and the main force hole 10.3 of the end of the main force arm 10.1 of the large lever 10, the pin 18, the fulcrum hole 7.5 of the side shift lever 7 of the third machine 26 and the positioning pin 24 are mounted in the positioning hole 22.6 in the housing 22, the fulcrum hole 6.5 of the long bent lever 6 of the fourth machine 27 and the positioning pin 24 are mounted in the positioning hole 22.7 in the housing 22. The fulcrum hole 10.5 of the large lever 10 is arranged on the positioning hole 22.8 in the shell 22, and the positioning pin 24 is inserted. In fig. 36, the extension and retraction directions of the cross bar 20 of the third machine 26 and the cross bar 20 of the fourth machine 27 are opposite, and the machines are in inverted relation to each other. Therefore, the power of the straight-moving motor can be continuously increased by connecting a plurality of motors in series.

Fig. 37 is a side shift lever 7 composed of 3-10 side shift levers 7 connected in parallel, reference numeral 18 denotes a pin, reference numeral 19 denotes a collar, reference numeral 28 denotes a washer between fulcrum holes 7.5 of the side shift lever 7, and reference numeral 24 denotes a positioning pin. The upper part of the overview fig. 37 is the E-diagram of fig. 35, and the lower part is the F-diagram of fig. 36. Fig. 38 shows that the negative force hole 10.4 of the large lever 10 is connected with the upper hole 11.1 of the push rod 11, the latch pin 18 and the upper collar 19 are connected with the pull hole 11.3 of the push rod and the upper hole 12.1 of the pull rod 12, the latch pin 18 and the upper collar 19 are connected with the lower hole 11.2 of the push rod 11 and the end push hole 14.3 of the lever 14.2 of the driving right-end ratchet wheel 14 in the B-view of fig. 29, the latch pin 18 and the upper collar 19 are connected with the lower hole 12.2 of the pull rod 12 and the end pull hole 13.3 of the lever 13.2 of the driving left-end ratchet wheel 13 (shielded) in the B-view of fig. 29, and the latch pin 18 and the upper collar 19 are connected. In fig. 38, reference numeral 15 is an internal spline housing of the driven left and right ratchet gears, and 15.5 is an internal spline.

From fig. 35 to fig. 38, the basic complete active power increasing machine of the negative force power distance of the negative force arm of the series-connection cross lever increasing lever is shown.

Fig. 39 is a main power increasing machine of the negative power moment of the negative force arm of the serial crossed lever increasing lever special for the highway sports car. The machine is characterized in that 3-10 branch point holes 8.5 which are connected in parallel to form a group of special levers 8 are arranged on a positioning hole 22.9 in a machine shell 22, a positioning pin 24 is inserted, a connecting hole 2.3 of a tail end connecting rod 2 of a first machine 23 is connected with a main force hole 8.3 of the special lever 8, a bolt pin 18 and an upper clamping ring 19 are connected, a negative force hole 8.4 of the special lever 8 is connected with one end supporting hole 9.1 of a group of special supporting rods 9 which are connected in parallel by 3-10, the bolt pin 18 and the upper clamping ring 19 are connected, the other end supporting hole 9.1 of the special supporting rod 9 is connected with a main force hole 5.3 of a short bending lever 5 of a second machine 25, and the bolt pin 18 and the upper clamping ring 19 are arranged in a road roadster head so as to prevent the sight of a driver from being shielded due to the fact that the distance between the first machine 23 and the second machine 25 is close. The rear part of the machine is omitted, and only the special lever 8 is used.

The push-pull rod 21.1 of the straight motor 21 of the first machine 23 makes telescopic reciprocating main power movement to drive the main power hole 5.3 of the short bent lever 5 connected with the end hole 21.2 of the push-pull rod 21.1 and the short bent lever 5 to make swinging movement, and also drives the pull-push hole 5.7 of the short bent lever 5 to make swinging movement to drive the support rod 3 to make reciprocating movement and then drive the press pry rod 4 to make swinging movement; the short bent lever 5 also drives the negative force hole 5.4 to do swinging negative work movement, and then drives the additional group cross lever 1 to do swinging movement; the press pry bar 4 and the added cross lever 1 are folded to open and swing, and a string of cross levers 20 are also driven to stretch and retract to carry out reciprocating negative power movement, so that the connecting hole 2.3 of the tail end connecting rod 2 also carries out reciprocating negative power movement, the negative power distance of the reciprocating negative power movement carried out by the connecting hole 2.3 of the tail end connecting rod 2 is longer than that of the swinging negative power movement carried out by the negative force hole 5.4 of the short bending lever 5, namely, the reciprocating negative power movement carried out by the connecting hole 2.3 of the tail end connecting rod 2 replaces the swinging negative power movement carried out by the negative force hole 5.4 of the short bending lever 5 in a phase manner, the long negative power distance of the reciprocating negative power movement carried out by the connecting hole 2.3 of the tail end connecting rod 2 replaces the short negative power distance of the swinging negative power movement carried out by the negative force hole 5.4 of the short bending lever 5 in a phase manner, the negative power amount carried out by the negative force hole 5.4 of the short bending lever 5 is increased in a phase manner, and the negative power change is increased by the negative power of the negative force of the main bending lever 5.4, and the negative power of the main bending lever 5 is also increased in a reverse direction. The first machine 23 drives the main force hole 6.3 of the long bent lever 6 of the second machine 25 connected with the connecting hole 2.3 of the tail end connecting rod 2 of the first machine 23 to perform swinging motion, drives the long bent lever 6 to perform swinging motion, drives the connecting hole 2.3 of the tail end connecting rod 2 of the second machine 25 to perform reciprocating negative power motion, drives the main force hole 7.3 of the lateral offset shift lever 7 of the third machine 26 connected with the connecting hole 2.3 of the tail end connecting rod 2 of the second machine 25 to perform swinging motion, drives the connecting hole 2.3 of the tail end connecting rod 2 of the third machine 26 to perform reciprocating negative power motion, drives the main force hole 6.3 of the long bent lever 6 of the fourth machine 27 connected with the connecting hole 2.3 of the tail end connecting rod 2 of the third machine 26 to perform swinging motion, drives the connecting hole 2.3 of the tail end connecting rod 2 of the fourth machine 27 to perform reciprocating negative power motion, drives the connecting hole 10.3 of the connecting rod 2.3 of the tail end connecting rod 2 of the fourth machine 27 to perform reciprocating negative power motion, and drives the main force hole 10.3 of the connecting rod 2, 10.3 of the connecting rod 2 to perform reciprocating motion, and then drives the main force hole 10.3 of the main force hole 11.3 of the connecting rod 11 to perform negative power hole 10.3 of the main force hole 11 and 10.3 of the main force hole of the connecting rod 11 and 10.3 of the connecting rod 11; the push rod 11 drives the upper hole 12.1 of the pull rod 12 connected with the pull hole 11.3 of the push rod 11 to do reciprocating motion, and also drives the pull rod 12 to do reciprocating motion. The push rod 11 drives a push hole 14.3 at the end of a lever 14.2 of the driving right ratchet gear 14 connected with a lower hole 11.2 of the push rod 11 to do swinging motion, and also drives the driving right ratchet gear to do swinging motion; the pull rod 12 drives the pull hole 13.3 at the end of the lever 13.2 of the driving left ratchet gear 13 connected with the lower hole 12.2 of the pull rod 12 to swing, and also drives the driving left ratchet gear to swing. The driving right-end ratchet gear and the driving left-end ratchet gear do swinging motion and are mutually replaced to drive the driven left-end and right-end ratchet gear internal spline housing to rotate to output power. Because the first machine, the second machine, the third machine and the fourth machine are connected in series to do negative work movement, the connecting hole 2.3 of the tail end connecting rod 2 of the fourth machine 27 increases the negative work amount and the negative power of the negative work movement to and fro, and is far greater than the active work and the active power of the main power source straight-moving motor 21.

If the crankshaft is used as the terminal transmission mechanism, and the machine suddenly breaks down and stops running, under the action of inertia, the serial cross lever runs like the situation that the serial cross lever in a figure 33 stretches out, the serial cross lever does not retract at the moment, the jacking force of the serial cross lever is very large, the crankshaft can be pushed to be dead through the transmission mechanism (such as a connecting rod) and cannot move, and the crankshaft can crush the serial cross lever under the action of inertia, so that sudden stop or traffic accidents, such as rear-end collision, can be caused when the serial cross lever is used on road vehicles. Only end ratchet gears can be used as the terminal force transmission mechanism.

Claims (4)

1. The utility model provides a series connection is alternately lever increases initiative power increase machine of lever negative force arm negative power work distance, includes alternately lever (1), terminal connecting rod (2), bracing piece (3), presses pinch bar (4), short curved lever (5), long curved lever (6), side offset shift lever (7), special lever (8), special bracing piece (9), straight motor (21), its characterized in that: a push-pull rod end hole (21.2) of the straight-moving motor (21) andfirst machine(23) The main force holes (5.3) of a group of short parallel-connected bent levers (5) are connected, the pull-push holes (5.7) of the short parallel-connected bent levers (5) are connected with the support holes (3.1) at one end of a group of parallel-connected support levers (3) without edges (3.3), the support holes (3.1) at the other end of the support levers (3) are connected with the main force holes (4.5) of a group of parallel-connected press pry levers (4), the support holes (5.6) of the parallel-connected short bent levers (5) are connected with the support holes (3.1) of another group of parallel-connected support levers (3), the support holes (3.2) at the other end of the other group of parallel-connected support levers (3) are connected with the support holes (4.6) of the parallel-connected press pry levers (4), the negative force hole (5.4) of the short bending lever (5) which is connected in parallel is connected with the force transmission hole (1.2) of a group of the additional cross levers which are connected in parallel, the fulcrum hole (1.3) of the additional cross levers which are connected in parallel is connected with the fulcrum hole (4.8) of the pressure pry bar (4), the fulcrum hole (5.5) of the short bending lever (5) of the first machine (23) is arranged on the positioning hole (22.1) in the machine shell (22), the positioning pin (24) is inserted, the connecting hole (2.3) of the tail end connecting rod (2) of the first machine (23) is connected with the main force hole (6.3) of the end of the main force arm (6.1) of the long bending lever (6) of the second machine (25), mounting a fulcrum hole (6.5) of a long bent lever (6) of a second machine (25) on a positioning hole (22.5) in a machine shell (22), inserting a positioning pin (24), and laterally shifting a connecting hole (2.3) of a tail end connecting rod (2) of the second machine (25) and a third machine (26)The main force hole (7.3) at the end of the main force arm (7.1) of the position lever (7) is connected, the branch point hole (7.5) of the laterally-deviated position lever (7) of the third machine (26) is installed on the positioning hole (22.6) in the shell (22), the positioning pin (24) is inserted, the connecting hole (2.3) of the tail end connecting rod (2) of the third machine (26) is connected with the main force hole (6.3) at the end of the main force arm (6.1) of the long bending lever (6) of the fourth machine (27), the branch point hole (6.5) of the long bending lever (6) of the fourth machine (27) is installed on the positioning hole (22.7) in the shell (22), the positioning pin (24) is inserted, the connecting hole (2.3) of the tail end connecting rod (2) of the fourth machine (27) is connected with the main force hole (10.3) of the main force arm (10.1) of the large lever (10), the connecting hole (10.5) of the connecting rod (10) is installed on the main force arm (10.1) of the push rod (22), the pull rod (22) of the pull rod (5) and the push rod (22.5) of the push rod (11) is connected with the push rod (10.5), inserting a positioning pin (24), connecting a connecting hole (2.3) of a tail end connecting rod (2) of a first machine (23) with a main force hole (8.3) of a special lever (8), connecting a negative force hole (8.4) of the special lever (8) with a supporting hole (9.1) at one end of a special supporting rod (9) which is formed into a group by 3-10, and connecting a supporting hole (9.1) at the other end of the special supporting rod (9) with a main force hole (5.3) of a short bent lever (5) of a second machine (25); all hole-to-hole connections are made with a dowel inserted into the pin (18) and a collar (19) fitted.

2. The active power increasing machine for increasing the negative power moment of the negative arm of the series-connection crossed lever according to claim 1, characterized in that: the cross lever (1) is a pair of cross lever groups formed by inserting pins (18) into the branch point holes (1.3) aligned and connected and then mounting a collar (19) on the ring groove at the tail end of the pin.

3. The active power amplifier of the negative moment of power of the negative arm of the series-connection cross lever extension lever of claim 1, wherein: the cross levers (1) are a pair of cross levers (17) which are vertically crossed with each other, the pair of cross levers are formed by alternately inserting one group of parallel cross levers and the other group of parallel cross levers, aligning and connecting branch point holes (1.3) of the two groups of cross levers, inserting pins (18) into the branch point holes, and arranging a collar (19) on a ring groove at the tail end of each pin; the two groups of crossed levers are mutually vertically crossed to form a pair of crossed levers (17), the force transmission holes (1.2) of one group of parallel crossed levers (17.1) of the first pair of crossed levers are connected with the force transmission holes (1.2) of one group of parallel crossed levers (17.2) of the second pair of crossed levers, and the two groups of crossed levers are inserted into a pin (18) and are provided with a clamping ring (19).

4. The active power amplifier of the negative moment of power of the negative arm of the series-connection cross lever extension lever of claim 3, wherein: the force transmission holes (1.2) of the other group of the parallel crossed levers (17.2) of the first pair of crossed levers are connected with the force transmission holes (1.2) of the other group of the parallel crossed levers (17.1) of the second pair of crossed levers, the multiple pairs of crossed levers are connected in series to form a string of crossed levers (20), the two force transmission holes (1.2) at one end of the string of crossed levers (20) are respectively connected with the force transmission holes (1.2) of the additional group of crossed levers (1) and the negative force holes (4.7) of the press prying rods (4), the two force transmission holes (1.2) at the other end of the string of crossed levers (20) are respectively connected with the main force holes (2.1) of the group of parallel connected end connecting rods (2) and the support holes (3.2) of the group of parallel connected support rods (3), the support point holes (2.2) of the end connecting rods (2) are respectively connected with the support holes (3.1) at the other ends of the support rods (3), and all the combined holes connected with the inserting holes are connected with the pin (18) and are connected with the clamping rings (19).

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