阅读说明：本技术 曲轴式双点压力机传动定位结构及同步精度调节方法 (Crankshaft type double-point press transmission positioning structure and synchronous precision adjusting method ) 是由 周德宝 林海龙 于 2019-11-18 设计创作，主要内容包括：本发明公开了一种曲轴式双点压力机传动定位结构及同步精度调节方法,通过对第一曲轴与第二曲轴的等高校正,并采用传动定位结构与驱动齿轮连接,大幅提升个传动组件之间的同步性。(The invention discloses a transmission positioning structure and a synchronization precision adjusting method of a crankshaft type double-point press, which greatly improve the synchronization among transmission components by correcting the equal heights of a first crankshaft and a second crankshaft and connecting the transmission positioning structure with a driving gear.)

1. The utility model provides a two point press transmission location structure of bent axle which characterized in that includes:

a crankshaft including a connection end (811);

the driving gear is provided with a mounting hole (821) for clamping the connecting end (811); and

a positioning pin (822) for connecting the crankshaft and the drive gear;

the inner wall of the mounting hole (821) is provided with a first positioning groove, the outer wall of the connecting end (811) is provided with a second positioning groove, the first positioning groove and the second positioning groove are combined to form a positioning hole (823), and the positioning pin (822) is clamped in the positioning hole (823).

2. The transmission positioning structure of crankshaft type double-point press as claimed in claim 1, wherein at least one positioning hole (823) is formed and circumferentially and uniformly distributed with an axis of the connecting end (811).

3. The transmission positioning structure of the crankshaft type double-point press is characterized in that the end face of the connecting end (811) is welded and fixed with the outer edge of the end face of the mounting hole (821).

4. A synchronous precision adjusting method of a crankshaft type double-point press machine, wherein the crankshaft type double-point press machine comprises a transmission mechanism, the transmission mechanism comprises a first transmission assembly (8) and a second transmission assembly (9), the first transmission assembly (8) comprises a first crankshaft (81) and a first driving gear (82) connected with the first crankshaft (81), the second transmission assembly (9) comprises a second crankshaft (91) and a second driving gear (92) connected with the second crankshaft (91), and the synchronous precision adjusting method is characterized by comprising the following steps:

1) adjusting the levelness of the upper end surface of the cross beam (2) to enable the upper end surface of the cross beam (2) to be in a horizontal state;

2) installing a first crankshaft (81) and a second crankshaft (91) into a cross beam (2), wherein the position of a first crank throw (813) of the first crankshaft (81) and the position of a second crank throw (912) of the second crankshaft (91) are on the same horizontal position, and the axis of a first connecting rod crank neck (8131) of the first crank throw (813) is parallel to the axis of a second connecting rod crank neck (9121) of the second crank throw (912);

3) rotating the first crankshaft (81) and the second crankshaft (91) such that the first throw (813) and the second throw (912) are both at a bottom dead center position;

4) a flat ruler (30) is erected and fixed on the upper end face of the cross beam (2), the flat ruler (30) is positioned above the two first crank throws (813) and the second crank throws (912), and a dial indicator (40) is suspended on the flat ruler (30), so that the axis of a measuring rod (41) of the dial indicator (40) is perpendicular to the axis of a first connecting rod crank neck (8131) or a second connecting rod crank neck (9121);

5) downwards moving the dial indicator (40) to enable the measuring head to abut against the outer wall of the first connecting rod bent neck (8131), horizontally sliding the dial indicator (40) to enable the measuring head to slide on the outer wall of the first connecting rod bent neck (8131), measuring circular runout, stopping the dial indicator (40) at the position with the maximum reading value, and enabling the reading value to return to zero;

6) sliding the dial indicator (40) towards the second crankshaft (91), wherein the sliding distance is the center distance L between the two main shafts of the first crankshaft (81) and the second crankshaft (91), enabling a measuring head of the dial indicator (40) to abut against the outer wall of the second connecting rod crank neck (9121), rotating the second crankshaft (91), observing the reading of the dial indicator (40), enabling the reading of the dial indicator (40) to be within plus or minus 0.02mm, completing the correction of the second crankshaft (91), and marking the positions of the first crank throw (813) and the second crank throw (912) on the cross beam (2) at the moment;

7) the first driving gear (82) is connected with the first crankshaft (81), the second driving gear (92) is connected with the second crankshaft (91), wherein the transmission positioning structure between the first driving gear (82) and the first crankshaft (81) and/or the transmission positioning structure between the second driving gear (92) and the second crankshaft (91) adopts the transmission positioning structure of the crankshaft type double-point press as claimed in any one of claims 1 to 3.

5. The method for adjusting the synchronization accuracy of a crankshaft type double-point press according to claim 4, further comprising a calibration verification step after the step 6), wherein the calibration verification step comprises the following operations:

rotating the first crankshaft (81) by any angle theta;

according to the operation mode of the step 5), finding the position where the reading of the dial indicator (40) on the first connecting rod bent neck (8131) is the maximum, and resetting the reading;

measuring to obtain the horizontal distance between the axis of the measuring rod (41) of the dial indicator (40) and the vertical plane where the circle center of the main shaft of the first crankshaft (81) is located, and recording the horizontal distance as L₁When the first crank (813) is between the two main shafts, L₁The value is negative, and the rotational position, L, of the other first bell crank (813)₁The value is positive;

sliding the dial indicator (40) towards the second crankshaft (91) with a sliding distance of L +2L₁And then, the second crankshaft (91) rotates by an angle theta in the direction opposite to the rotation direction of the first crankshaft (81), reading the reading of the measuring head of the dial indicator (40) on the second connecting rod bent neck (9121) at the moment, verifying whether the reading of the dial indicator (40) is between plus or minus 0.02mm, indicating that the second crankshaft (91) is corrected in place if the reading is between plus or minus 0.02mm, and otherwise, re-executing the steps 3) to 6 if the second crankshaft (91) is not corrected in place.

6. The synchronous accuracy adjustment method of crankshaft type double-point press according to claim 5, characterized in that the center distance L between the two main shafts of the first crankshaft (81) and the second crankshaft (91) is measured by binding plumb lines (60) on the two main shafts, and the horizontal distance between the two plumb lines (60) is measured and is the center distance L.

7. The synchronous precision adjustment method of crankshaft type double-point press according to claim 4, characterized in that the levelness adjustment of the upper end surface of the cross beam (2) in step 1) comprises the following operations:

the beam (2) is erected on the frame (1) in advance, and the bottom of the frame (1) is provided with a foot cup or an adjusting pad (11);

the leveling ruler (30) is placed at the upper end face of the cross beam (2), and the levelness of the upper end face of the cross beam (2) is adjusted by observing the adjusting function of the leveling ruler (30) matched with the foot cup or the adjusting pad (11).

8. The synchronous precision adjusting method of the crankshaft type double-point press machine according to claim 4, characterized in that in step 3), the counterweight (50) is hung on the first crank throw (813) and the second crank throw (912), and the first crank throw (813) and the second crank throw (912) freely droop and rotate to the bottom dead center position under the action of gravity.

9. The synchronous accuracy adjusting method of crankshaft type double-point press according to claim 4, characterized in that the installation manner between the first driving gear (82) and the first crankshaft (81) in step 7) is the same as the installation manner between the second driving gear (92) and the second crankshaft (91), and the method comprises the following operation steps:

after a connecting end (811) of the first crankshaft (81) or the second crankshaft (91) is correspondingly clamped into a mounting hole (821) of the first driving gear (82) or the second driving gear (92), multi-spot welding is carried out on the contact position of the connecting end (811) and the mounting hole (821) to realize prepositioning;

then, boring is carried out on the contact surface of the connecting end (811) and the mounting hole (821) to form a positioning hole (823), and the positions of the welding point and the positioning hole (823) are staggered;

finally, the positioning pin (822) is clamped into the positioning hole (823).

10. The synchronous precision adjusting method of the crankshaft type double-point press machine according to claim 9, characterized in that the locating pin (822) is put into liquid nitrogen in advance for cooling for 2-3min before being clamped into the locating hole (823), and the interference amount of the locating pin is controlled to be 0.02-0.03 mm.

Technical Field

The invention relates to the technical field of forging equipment, in particular to a transmission positioning structure of a crankshaft type double-point press and a synchronous precision adjusting method.

Background

With the rapid development of the industry, the forging equipment manufacturing industry is also developed. Mechanical presses are widely used in industrial processes as a representative forging apparatus. The mechanical press is classified according to a transmission mode and mainly comprises a crankshaft type and an eccentric gear type, the working principles of the crankshaft type and the eccentric gear type are similar, the reciprocating motion of a driving connecting rod is taken as a core, and the connecting rod drives a guide pillar to reciprocate in a guide sleeve in the reciprocating motion process, so that the continuous die closing and separating actions are realized.

Each link mechanism in the mechanical press is called as a 'point', two-point presses are provided with two link mechanisms, and the four-point presses with the two-point presses or more link mechanisms have larger working platforms compared with single-point presses, so that the mechanical press is suitable for forming multi-station workpieces. Meanwhile, the requirement of the double-point press or the four-point press on the synchronism of each set of link mechanism is relatively high, and the synchronism precision of each set of link mechanism directly influences the qualification rate of the stamping products and the service life of the stamping die.

Therefore, the market carries out the precision adjustment of the synchronism before the mechanical press is shipped out. In the utility model patent with the publication number of CN206794470U, a device for checking the crankshaft height of a crankshaft type double-point press is disclosed, and the operation method is as follows: a left milling square and a right milling square are milled on a transmission shaft in advance and serve as mounting positions of a base of the dial indicator, and the equal height adjustment of the two crankshafts is achieved by comparing the reading difference of the two dial indicators at the positions of the left crank throw and the right crank throw. However, in each set of link mechanism, the crankshaft is driven by the gear to rotate, and the matching precision between the crankshaft and the gear also influences the synchronization precision. In the prior art, the connection between the crankshaft and the gear is generally connected by key, and the key is often not high in matching precision, so that the synchronization precision of each set of connecting rod mechanism is influenced.

Disclosure of Invention

The invention aims to provide a transmission positioning structure of a crankshaft type double-point press, which improves the matching precision between a crankshaft and a gear.

The above object of the present invention is achieved by the following technical solutions:

a crankshaft type double-point press transmission positioning structure comprises:

a crankshaft including a connection end;

the driving gear is provided with a mounting hole for clamping the connecting end; and

the positioning pin is used for connecting the crankshaft and the driving gear;

the inner wall of the mounting hole is provided with a first positioning groove, the outer wall of the connecting end is provided with a second positioning groove, the first positioning groove and the second positioning groove are combined to form a positioning hole, and the positioning pin is clamped in the positioning hole.

Through adopting above-mentioned technical scheme, utilize the locating pin to replace the location cooperation that the key realized between bent axle and the drive gear, two bent axles are after high correction such as completion, and the link card of bent axle is gone into to the mounting hole of drive gear, compares the keyway, and locating hole cross sectional shape is certain, forms through the bore hole, and the machining precision is higher relatively, promotes the positioning precision between bent axle and the drive gear.

Meanwhile, after the positioning pin is clamped into the positioning hole, the crankshaft and the driving gear are matched by the positioning pin, and compared with key matching, the positioning precision is higher in matching positioning precision, so that the synchronism of the two crankshafts is also ensured; and, the locating pin is when the locating hole is gone into to the card, because the locating pin is along direction of height diameter homogeneous relatively, can adopt expend with heat and contract with cold the mode and install, the installation process range is less, it is lower to the relative position influence of two bent axles, the synchronism of two bent axles during operation of assurance that can be better, and when carrying out the synchronism through the key-type connection mode and transferring, the key of adoption is the deformed key, use Z type key as the key commonly used, then need pass through great striking power to the installation of key, commonly known as "join in marriage key method", need continuous retouching to make it reach large tracts of land contact cooperation, need use powerful striking power at the in-process of cooperation, influence the relative position between two bent axles and keep easily, influence the synchronism during operation.

Preferably, at least one positioning hole is formed and is circumferentially and uniformly distributed by the axis of the connecting end.

By adopting the technical scheme, the positioning accuracy and the connection strength between the crankshaft and the driving gear are further improved due to the arrangement of the positioning holes, when the positioning is matched, one positioning hole serves as a positioning point between the crankshaft and the driving gear, and the rest positioning holes serve as the functions of improving the connection strength between the crankshaft and the driving gear and assisting in improving the positioning accuracy of the crankshaft and the driving gear.

Preferably, the end face of the connecting end is welded and fixed with the outer edge of the end face of the mounting hole.

Through adopting above-mentioned technical scheme, the bent axle carries out welding position in advance when cooperating with drive gear, and when reducible later stage processing locating hole, the bent axle takes place to rotate relative drive gear, and destroys the relative position between two bent axles and keeps.

The invention aims to provide a synchronous precision adjusting method of a crankshaft type double-point press, which improves the synchronism among transmission assemblies.

The above object of the present invention is achieved by the following technical solutions:

the utility model provides a synchronous precision adjustment method of bent axle formula two point press, bent axle formula two point press includes drive mechanism, drive mechanism includes first transmission subassembly and second transmission subassembly, first transmission subassembly includes first bent axle and the first drive gear who is connected with first bent axle, second transmission subassembly includes second bent axle and the second drive gear who is connected with the second bent axle, includes following step:

1) adjusting the levelness of the upper end surface of the cross beam to enable the upper end surface of the cross beam to be in a horizontal state;

2) installing a first crankshaft and a second crankshaft into a cross beam, wherein a first crank throw position of the first crankshaft and a second crank throw position of the second crankshaft are positioned on the same horizontal position, and meanwhile, the axis of a first connecting rod crank neck of the first crank throw is parallel to the axis of a second connecting rod crank neck of the second crank throw;

3) rotating the first crankshaft and the second crankshaft to enable the first crank throw and the second crank throw to be located at the bottom dead center position;

4) a flat ruler is erected and fixed on the upper end face of the cross beam, the position of the flat ruler is simultaneously positioned above the two first crank throws and the second crank throws, and a dial indicator is hung on the flat ruler, so that the axis of a measuring rod of the dial indicator is perpendicular to the axis of the first connecting rod crank neck or the second connecting rod crank neck;

5) moving down the dial indicator to enable the measuring head to abut against the outer wall of the first connecting rod bent neck, horizontally sliding the dial indicator to enable the measuring head to slide on the outer wall of the first connecting rod bent neck, performing circular runout measurement, stopping the dial indicator at the position with the maximum reading value, and enabling the reading value to return to zero;

6) sliding the dial indicator towards the second crankshaft, wherein the sliding distance is the center distance L between the two main shafts of the first crankshaft and the second crankshaft, enabling a measuring head of the dial indicator to abut against the outer wall of the second connecting rod crank neck, rotating the second crankshaft, observing the reading of the dial indicator, enabling the reading of the dial indicator to be within plus or minus 0.02mm, completing the correction of the second crankshaft, and marking the positions of the first crank throw and the second crank throw on the cross beam;

7) a first driving gear is connected with a first crankshaft, a second driving gear is connected with a second crankshaft, wherein a transmission positioning structure between the first driving gear and the first crankshaft and/or a transmission positioning structure between the second driving gear and the second crankshaft adopt the transmission positioning structure of the crankshaft type double-point press as claimed in any one of claims 1-3.

By adopting the technical scheme, the synchronous precision adjustment of the double-point press mainly aims at the adjustment of the relative positions of the two crankshafts, and the levelness of the upper end surface of the front cross beam is adjusted in advance, so that when the flat ruler is placed on the cross beam, the flat ruler has better levelness. After the two crankshafts are pre-installed in the cross beam, when the relative positions of the two crankshafts are adjusted, the first crankshaft and the second crankshaft are both adjusted to the bottom dead center position, the first crank throw and the second crank throw freely droop under the action of gravity, the precision of the bottom dead center position can be better guaranteed, and the correction precision is improved. In the correction process, the dial indicator is hung on a leveling rod for completing levelness adjustment, the maximum value of the reading is taken, namely the highest point of the position of the first connecting rod bent neck is obtained, the dial indicator horizontally slides to the position above the correction crankshaft along the leveling rod under the condition that the vertical height of the dial indicator is unchanged, the second crankshaft is corrected, and the precision adjustment of the relative position of the two crankshafts is completed. And then the first driving gear and the second driving gear are installed and connected, and in the installation process, a positioning structure of a positioning pin is adopted between the driving gear and the crankshaft, so that the matching precision between the crankshaft and the driving gear is improved, the vibration of the crankshaft in the connection process with the driving gear is reduced, the relative position between the two crankshafts which are corrected is damaged, and the working synchronism of the two transmission assemblies is better improved.

Preferably, a correction verification step is further included after step 6), the correction verification step including the following operations:

rotating the first crankshaft by any angle theta;

according to the operation mode of the step 5), finding the position where the dial indicator is located at the maximum reading position of the first connecting rod bent neck, and resetting the reading position;

measuring to obtain the horizontal distance between the axis of the measuring rod of the dial indicator and the vertical plane where the circle center of the main shaft of the first crankshaft is positioned, and recording the horizontal distance as L₁When the first crank throw is between the two main shafts, L₁Negative in value, other first crank rotation position, L₁The value is positive;

sliding the dial indicator towards the direction of the second crankshaft for a sliding distance of L +2L₁And then, the second crankshaft rotates by an angle theta in the direction opposite to the rotation direction of the first crankshaft, reading the reading of the measuring head of the dial indicator on the second connecting rod crank neck at the moment, verifying whether the reading of the dial indicator is between plus or minus 0.02mm, indicating that the second crankshaft is corrected in place if the reading is between plus or minus 0.02mm, and otherwise, re-executing the steps 3) to 6).

By adopting the technical scheme, after the relative position correction is completed, the verification of the relative position accuracy is carried out on the second crankshaft to improve the correction accuracy. During verification, the circle center distance L between the two main shafts of the first crankshaft and the second crankshaft is fixed, the first crankshaft rotates for any angle, the dial indicator finds the maximum value position of the outer wall reading of the first connecting rod bent neck, namely the highest point of the first connecting rod bent neck, and the L measured at the moment is obtained₁Horizontal sliding distance L +2L of dial indicator₁And then, namely the theoretical position, namely the verification position, of the position to which the second crankshaft should rotate within the correction precision error is obtained, the second crankshaft rotates in the reverse direction by the same angle as that of the first crankshaft, at the moment, if the numerical value obtained by the dial indicator is within the range of 0.02mm, the first correction position is accurate, and if the numerical value is greater than 0.02mm, the first correction position has an error and needs to be corrected again. This verify the mode for the percentage table can comparatively accurate horizontal slip to the verification position of second bent axle, and it is higher relatively to verify the precision, better promotes the regulation precision between two bent axles.

Preferably, the center distance L between the two main shafts of the first crankshaft and the second crankshaft is measured by binding plumb lines on the two main shafts, and the horizontal distance between the two plumb lines is obtained through measurement, namely, the center distance L.

By adopting the technical scheme, the vertical degree of the plumb line and the balance weight of the plumb line are utilized, the central vertical planes of the two main shafts are automatically found, the center distance L is obtained by measuring the horizontal distance between the two plumb lines, the measuring mode is relatively simple, and the measuring precision is relatively high.

Preferably, the levelness adjustment of the upper end surface of the cross beam in the step 1) comprises the following operations:

the crossbeam is erected on the frame in advance, the bottom of the frame is provided with a foot cup or an adjusting pad;

the leveling ruler is placed at the upper end face of the cross beam, and levelness adjustment of the upper end face of the cross beam is completed by observing the adjusting function of the leveling ruler in cooperation with the foot cup or the adjusting pad.

Through adopting above-mentioned technical scheme, the levelness of crossbeam up end directly influences the levelness of ruler, and then influences the position on percentage table measuring head and the connecting rod bent neck, and utilizes the foot cup or the adjustment pad realization of ruler cooperation frame bottom to the levelness regulation of crossbeam up end, adjusts easy operation.

Preferably, in step 3), a counterweight is hung on the first crank throw and the second crank throw, and the first crank throw and the second crank throw freely droop under the action of gravity and rotate to the bottom dead center position.

Through adopting above-mentioned technical scheme, first bent axle and second bent axle install back in the crossbeam in advance, and the both ends of main shaft are in rotating to be connected in the crossbeam, because first crank throw and second crank throw be eccentric settings, can take place free flagging at the action of gravity, and hang the balancing weight again in addition and overcome the damping of main shaft both ends relative rotation in the crossbeam for first crank throw and second crank throw are more accurate be in the bottom dead center position, improve the correction precision.

Preferably, the step 7) of mounting the first driving gear and the first crankshaft in the same way as the second driving gear and the second crankshaft comprises the following operation steps:

after the connecting end of the first crankshaft or the second crankshaft is correspondingly clamped in the mounting hole of the first driving gear or the second driving gear, multi-spot welding is carried out on the contact position of the connecting end and the mounting hole to realize pre-positioning;

then, boring holes on the contact surface of the connecting end and the mounting hole to form positioning holes, wherein the positions of welding points and the positioning holes are staggered;

and finally, clamping a positioning pin in the positioning hole.

Through adopting above-mentioned technical scheme, accomplish the correction back of first bent axle and second bent axle, install first drive gear and second drive gear, in the installation, adopt the multiple spot welding mode in advance to realize being connected between first bent axle and first drive gear and second bent axle and the second drive gear, improve being connected and positioning accuracy between bent axle and the drive gear through seting up locating hole cooperation locating pin afterwards, better promote each transmission assembly's synchronism.

Preferably, before the positioning pin is clamped into the positioning hole, the positioning pin is placed into liquid nitrogen in advance for cooling for 2-3min, and the interference amount of the positioning pin is controlled to be 0.02-0.03 mm.

By adopting the technical scheme, the positioning pin is cooled and contracted by using liquid nitrogen, the positioning pin with the contracted size is more easily arranged in the positioning hole, and the size automatically expands after the temperature of the positioning pin is raised to room temperature, so that the matching between the crankshaft and the driving gear is realized; in addition, the locating pin after the size shrink is when the card is gone into to the locating hole, and the installation can reduce the outside dynamics of knocking to the locating pin simultaneously comparatively simply, reduces the influence to the crankshaft position after having accomplished the regulation.

In conclusion, the beneficial technical effects of the invention are as follows:

1. the crossbeam is installed with the frame in advance, so that the operation of later-stage device assembly can be reduced, the levelness of the upper end face of the crossbeam is adjusted, the first crankshaft and the second crankshaft are ensured to have better levelness when being installed in the crossbeam, and the dial indicator has better verticality when being hung on the crossbeam, so that the correction precision is improved;

2. the first crankshaft and the second crankshaft are subjected to equal-height adjustment in a contrast mode, the first crankshaft serves as a reference crankshaft, the second crankshaft serves as a correction crankshaft, a bottom dead center position is selected as a reference correction position, the first crankshaft and the second crankshaft can freely droop under the self gravity, and the first crank throw and the second crank throw are matched with each other and provided with matching objects, so that the damping of two main shafts during rotation relative to the cross beam is overcome, the accuracy of the correction position is improved, and the correction accuracy is better improved;

3. a verification step is additionally arranged after the first crankshaft and the second crankshaft are corrected at the bottom dead center, and the dial indicator slides for a fixed distance to ensure the accuracy of verification positions and better improve the adjustment precision;

5. according to the multi-point welding type crankshaft and driving gear pre-connection structure, pre-connection between any crankshaft and the driving gear is completed in advance in a multi-point welding mode, the connection strength and the positioning accuracy are enhanced by matching with the positioning pin, meanwhile, the relative position of the two crankshafts after correction is completed is reduced when any crankshaft is connected with the driving gear, and the adjustment accuracy of the whole synchronism is better improved.

Drawings

FIG. 1 is a schematic view of a transmission positioning structure of a crankshaft type double-point press according to an embodiment;

FIG. 2 is a schematic view illustrating a location of a positioning hole between a connecting end and a mounting hole according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a crankshaft type double-point press showing mainly a transmission mechanism according to an embodiment;

FIG. 4 is a schematic structural diagram of a transmission mechanism of a crankshaft type double-point press in a top view according to an embodiment;

FIG. 5 is a formal drawing after a leveling ruler is installed when the leveling of the upper end surface of the cross beam is adjusted in the second embodiment;

FIG. 6 is a plan view of the second embodiment after the leveling ruler is installed for adjusting the level of the upper end surface of the cross beam;

FIG. 7 is a schematic view of the first and second crankshafts in a second embodiment as they are adjusted to bottom dead center;

FIG. 8 is a diagram illustrating the second embodiment of the dial gauge in the measurement of the jump of the first connecting rod crank;

FIG. 9 is a diagram illustrating the second embodiment of the dial indicator in the measurement of the jump of the second connecting rod bending neck;

FIG. 10 is a schematic view illustrating a state of measuring the distance between the centers of the first spindle and the second spindle according to the second embodiment;

FIG. 11 is a diagram illustrating the second embodiment in which the dial indicator measures the jump of the first connecting rod crank neck in the verification step;

FIG. 12 is a diagram illustrating a state where the percentage water is smoothed to the corrected position in the verification step according to the second embodiment;

FIG. 13 is a diagram illustrating a state where the second connecting rod is bent to abut against the measuring head of the dial indicator when the second connecting rod has passed the calibration accuracy in the second embodiment;

fig. 14 is a schematic diagram of a state when the second connecting rod is bent to abut against the measuring head of the dial indicator under the condition of unqualified correction precision in the second embodiment.

In the figure, 1, a frame; 11. an adjustment pad; 2. a cross beam; 21. a front plate; 22. a support plate; 23. a back plate; 3. a motor; 4. a flywheel; 5. a belt; 6. a drive gear shaft; 7. a high-speed gear; 8. a first transmission assembly; 81. a first crankshaft; 811. a connecting end; 812. a first main shaft; 813. a first crank throw; 8131. a first link flexure; 82. a first drive gear; 821. mounting holes; 822. positioning pins; 823. positioning holes; 9. a second transmission assembly; 91. a second crankshaft; 911. a second main shaft; 912. a second crank throw; 9121. a second connecting rod bending neck; 92. a second drive gear; 10. a guide post; 20. a guide sleeve; 30. leveling; 40. a dial indicator; 41. a measuring rod; 50. a balancing weight; 60. a plumb line; 70. and connecting the wires.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.