CN204556024U - A kind of thread take-up tension lever on-line vibration and flexural measurement device - Google Patents

Abstract

The utility model discloses a kind of thread take-up tension lever on-line vibration and flexural measurement device, comprise bend sensor, twist sensors, bending sensor, three acceleration transducers and scramblers etc.; Bend sensor and twist sensors are located on thread take-up tension lever connecting rod, and two acceleration transducers are located on thread take-up tension lever take-up arm, and bending sensor and another acceleration transducer are located in thread take-up tension lever vertical arm, and scrambler is located on the gear pair of axle on sewing machine; Bend sensor, twist sensors and bending sensor are all by Signal Collection and amplify device connection signal analyser; Three acceleration transducers are respectively by load amplifier connection signal analyser; Scrambler is by control panel connection signal analyser, and control panel is connected with Signal Collection and amplify device, and signal analyzer is connected with display screen.The utility model obtains by analysis to measure the dynamic data that thread take-up tension lever runs, and for the improvement of sewing machine or new design provide measurement data, reduces the bending and vibration that thread take-up tension lever is unnecessary at the volley.

Description

A kind of thread take-up tension lever on-line vibration and flexural measurement device

Technical field

The utility model relates to a kind of thread take-up tension lever pick-up unit of Yarn taking-up mechanism, is applied in the measuring technique of template sewing machine, is specifically related to a kind of thread take-up tension lever on-line vibration and flexural measurement device.

Background technology

In the Yarn taking-up mechanism of sewing machine, thread take-up tension lever makes planar reciprocating, and thread take-up tension lever has in minimum and extreme higher position that one section of standard is static, speed is the stage of zero, and thread take-up tension lever high vibration after take-up, unwrapping wire terminate, the thread take-up tension lever in motion produces bending and distortion.Thread take-up tension lever is structurally divided into connecting rod, vertical arm and take-up arm three part, and take-up arm and connecting rod be not at same plane, and tension force of facial suture acts on the projecting end of take-up arm, and take-up arm is a semi-girder.

Yarn taking-up mechanism is arranged on template sewing machine between axle and thread take-up tension lever, and mechanism converts the plane motion of thread take-up tension lever to the gyration of upper axle, and upper thread is via the eyelet of shank and thread take-up tension lever, and the motion with eyelet realizes feed and regains the action of upper thread.Template sewing machine is combined into one the crank of needle bar mechanism and Yarn taking-up mechanism, thread take-up tension lever significantly vibrate through crank directly affect shank motion stability.

The thread take-up tension lever of four lever take-up mechanism vibrates large especially in take-up process.Intrinsic Yarn taking-up mechanism belongs to vibrate mechanism that is large, bumpy motion.And high-speed industrial machine rotating speed is high, Yarn taking-up mechanism in use greatest problem is that vibration is large, and the vibration that in Yarn taking-up mechanism, take-up overtension causes causes needle tracking crooked.Sewing thread produces the dynamic loading that direction constantly changes, and sewing thread acting force acts on the end of take-up arm, and vertical arm and take-up arm produce bending, and take-up arm is platypelloid type, thickness thinnest part only 2.6 millimeters, there is very large vibration and distortion in the flat direction of take-up arm.The vibration shape of thread take-up tension lever is complicated and amplitude is large, especially produces violent oscillatory motion in the transverse direction of thread take-up tension lever motion.Therefore measure take-up vibration of bar and bending distortion, measure upper axle be turned back to which angle occur maximum bending, to reverse be the important element task of one, sewing machine.

Thread take-up tension lever does reciprocal plane motion, and the stressed direction of thread take-up tension lever is from eedle eyelet to the eyelet of thread take-up tension lever, and direction and the thread take-up tension lever direction of motion of power are space crossed, and thread take-up tension lever motion characteristics also there is vibration in two other direction perpendicular to direction of motion.Measure thread take-up tension lever acceleration, need to measure the vibration data perpendicular to operative orientation, these vibrations are unnecessary and harmful.

Upper axle travelling speed should avoid horizontal critical velocity, greatly reduces thread take-up tension lever and bends and vibration.Thread take-up tension lever case of bending is obtained by the measurement of foil gauge group, the vibrational state of thread take-up tension lever is recorded by acceleration transducer, just correctly can understand the force and deformation state of thread take-up tension lever from the deflection of thread take-up tension lever and the measured data of vibratory output, judge that whether the take-up course of work is normal by data.

Utility model content

In order to meet the demand, the utility model aims to provide a kind of thread take-up tension lever on-line vibration and flexural measurement device, the dynamic data of thread take-up tension lever operation is obtained by analysis to measure, for the transformation of existing Yarn taking-up mechanism technology and the design of new Yarn taking-up mechanism provide measurement data, reduce the bending and vibration that thread take-up tension lever is unnecessary at the volley.

For realizing above-mentioned technical purpose, reach above-mentioned technique effect, the utility model is achieved through the following technical solutions:

A kind of thread take-up tension lever on-line vibration and flexural measurement device, comprise bend sensor, twist sensors, bending sensor, Signal Collection and amplify device, first, second, third acceleration transducer, first, second, third load amplifier, scrambler, control panel and signal analyzer; Described bend sensor and described twist sensors are arranged on thread take-up tension lever connecting rod, described first acceleration transducer and described second acceleration transducer are separately positioned on thread take-up tension lever take-up arm, described bending sensor and described 3rd acceleration transducer are arranged in thread take-up tension lever vertical arm, and described scrambler is arranged on the gear pair of axle on sewing machine;

Described bend sensor, described twist sensors are all connected with described signal analyzer by described Signal Collection and amplify device with described bending sensor; Described first, second, third acceleration transducer is connected with described signal analyzer respectively by the described first, second, third load amplifier of correspondence; Described scrambler is connected with described signal analyzer by described control panel, and described control panel is connected with described Signal Collection and amplify device, and described signal analyzer is connected with a display screen.

Further, described bend sensor is pasted onto the side at 2mm thickness place in the middle part of described thread take-up tension lever connecting rod, measures the flexural deformation of thread take-up tension lever connecting rod holes center line connecting direction; Described bend sensor is made up of the first copper sheet of a slice 0.5 millimeters thick and four first foil gauges be pasted onto on described first copper sheet, and the stickup direction of described four first foil gauges is parallel to the thread take-up tension lever connecting rod holes line of centres.

Further, described twist sensors is pasted onto the opposite side at 2mm thickness place in the middle part of described thread take-up tension lever connecting rod, measures the torsional deformation of connecting rod holes center line connecting direction; Described twist sensors is made up of the second copper sheet of a slice 0.5 millimeters thick and four second foil gauges be pasted onto on described second copper sheet, and the stickup direction of described four second foil gauges becomes 45o angle with the thread take-up tension lever connecting rod holes line of centres.

Further, described bending sensor is pasted onto the lateral surface at 3.8mm thickness place in the middle part of described thread take-up tension lever vertical arm, described bending sensor is made up of the 3rd copper sheet of a slice 0.5 millimeters thick and eight the 3rd foil gauges be pasted onto on described 3rd copper sheet, the stickup direction of four described 3rd foil gauges is parallel with the vertical direction of described thread take-up tension lever vertical arm, measure the flexural deformation of vertical arm, the another stickup direction of four described 3rd foil gauges and the vertical direction angle at 45 ° of described thread take-up tension lever vertical arm, measure the torsional deformation of vertical arm.

Further, described first acceleration transducer is adsorbed on the side that a piece is measured bent plate, described measurement bent plate is fixed on described thread take-up tension lever take-up arm, and the take-up arm of described thread take-up tension lever is clipped in the middle by described measurement bent plate, and clamps described thread take-up tension lever take-up arm by bolt, nut and cushion cover.

Further, described second acceleration transducer is adsorbed on the end face of described thread take-up tension lever take-up arm, and direction of measurement is perpendicular to the direction of motion of take-up arm.

Further, described 3rd acceleration transducer is adsorbed on the side of described thread take-up tension lever vertical arm, and direction of measurement is perpendicular to the direction of motion of thread take-up tension lever.

Further, electric bridge, transmitter, signal recognition device and signal amplifier is comprised in described Signal Collection and amplify device, described electric bridge is respectively described bend sensor, described twist sensors and described bending sensor power, and described bend sensor, described twist sensors are connected with described signal recognition device through described transmitter respectively with described bending sensor; Described scrambler and described control panel composition clock signal control device, described scrambler is connected with described signal recognition device through described control panel; Described signal recognition device is connected with described signal analyzer through described signal amplifier.Scrambler produces the pivotal angle signal of axle on sewing machine, and output signal entering signal collection amplifier and the signal analyzer respectively of control panel, controls record and the display timing generator of each signal.

The beneficial effects of the utility model are as follows:

The utility model is that sewing machine provides a kind of measure measuring thread take-up tension lever bending and vibrational state, utilizes bridge-type foil gauge principle to measure the bending of thread take-up tension lever, from three orientation measurement thread take-up tension lever vibrational states.Obtaining the dynamic data of thread take-up tension lever operation by analyzing the utility model measurement, can improve for the mechanism design of high speed sewing machine and basis is provided, reduce the distortion that in motion, thread take-up tension lever is unnecessary as far as possible and bend.

Above-mentioned explanation is only the general introduction of technical solutions of the utility model, in order to better understand technological means of the present utility model, and can be implemented according to the content of instructions, coordinates accompanying drawing to describe in detail below with preferred embodiment of the present utility model.Embodiment of the present utility model is provided in detail by following examples and accompanying drawing thereof.

Accompanying drawing explanation

Accompanying drawing described herein is used to provide further understanding of the present utility model, and form a application's part, schematic description and description of the present utility model, for explaining the utility model, is not formed improper restriction of the present utility model.In the accompanying drawings:

Fig. 1 is one-piece construction block diagram of the present utility model;

Fig. 2 is the front elevation of thread take-up tension lever;

Fig. 3 is the vertical view of thread take-up tension lever;

Fig. 4 is the utility model bend sensor, twist sensors and the bending sensor installation site schematic diagram on thread take-up tension lever;

Fig. 5 is the C direction view of Fig. 4;

Fig. 6 is the B direction view of Fig. 4;

Fig. 7 is the A direction view of Fig. 4;

Fig. 8 is the structural representation of the utility model bend sensor;

Fig. 9 is the structural representation of the utility model twist sensors;

Figure 10 is the structural representation of the utility model bending sensor;

Figure 11 is the front elevation of the utility model first acceleration transducer installation site;

Figure 12 is the vertical view of the utility model first acceleration transducer installation site;

Figure 13 is the left view that the utility model measures bent plate;

Figure 14 is the vertical view that the utility model measures bent plate;

Figure 15 is the front elevation of second, third acceleration transducer installation site of the utility model;

Figure 16 is the front elevation of the utility model second acceleration transducer installation site;

Figure 17 is the work block diagram of the utility model thread take-up tension lever measurement of distortion and flexure signal.

Embodiment

Below with reference to the accompanying drawings and in conjunction with the embodiments, describe the utility model in detail.

Shown in Figure 1, a kind of thread take-up tension lever on-line vibration and flexural measurement device, comprise bend sensor 1, twist sensors 2, bending sensor 3, Signal Collection and amplify device 4, first, second, third acceleration transducer 5,6,7, first, second, third load amplifier 8,9,10, scrambler 11, control panel 12 and signal analyzer 13; Described bend sensor 1, described twist sensors 2 are all connected with described signal analyzer 13 by described Signal Collection and amplify device 4 with described bending sensor 3; Described first, second, third acceleration transducer 5,6,7 respectively by the described first, second, third load amplifier 8 of correspondence, 9,10 are connected with described signal analyzer 13; Described scrambler 11 is connected with described signal analyzer 13 by described control panel 12, and described control panel 12 is connected with described Signal Collection and amplify device 4, and described signal analyzer 13 is connected with a display screen 19.

Shown in Fig. 2,3, thread take-up tension lever is made up of parts such as connecting rod 14, vertical arm 16 and take-up arms 15, the major part of thread take-up tension lever is connecting rod 14, connecting rod 14 is exactly the motion rod member of four lever take-up mechanism, take-up arm 15 is adjutages of connecting rod 14, and take-up lever pin is installed in the end of take-up arm 15, and the aperture of take-up lever pin is 2 millimeters, length is 3 millimeters, and sewing thread is walked around from eyelet.Not at grade, connecting rod 14 is connected to take-up arm 15 through vertical arm 16 for take-up arm 15 and connecting rod 14.Connecting rod 14 has holes, and macropore diameter is 8 millimeters, is the hinge point of crank and connecting rod 14, and crank and connecting rod 14 form revolute pair, have bearing shell, needle bearing between crank and connecting rod 14; Small aperture is 5.2 millimeters, is the hinge point of fork and connecting rod 14, and fork and connecting rod 14 form revolute pair, have bearing shell between fork and connecting rod 14.

The utility model is a kind of thread take-up tension lever on-line vibration and flexural measurement device, utilizes bridge-type foil gauge principle to measure the bending of thread take-up tension lever, from three orientation measurement thread take-up tension lever vibrational states.The thread take-up tension lever vibration that dynamic loading is brought and bending distortion and the damage that can cause each parts of Yarn taking-up mechanism, by measuring the dynamic data obtaining thread take-up tension lever and run, basis can be provided for the mechanism design of high speed sewing machine or improvement, reduce distortion unnecessary in thread take-up tension lever motion as far as possible with bending.

1, the Part I measured adopts bend sensor 1, twist sensors 2 and bending sensor 3 to measure the distortion of thread take-up tension lever each several part.

Shown in Fig. 4-7, the deformation measuring point of thread take-up tension lever is selected on connecting rod 14 and vertical arm 16.Described bend sensor 1 is pasted onto the side at 2mm thickness place in the middle part of described thread take-up tension lever connecting rod 14, measures the flexural deformation of connecting rod 14; Described twist sensors 2 is pasted onto the opposite side at 2mm thickness place in the middle part of described thread take-up tension lever connecting rod 14, measures the torsional deformation of connecting rod 14; Described bending sensor 3 is pasted onto the lateral surface at 3.8mm thickness place in the middle part of described thread take-up tension lever vertical arm 16, measures flexural deformation and the torsional deformation of vertical arm 16.

Further, shown in Figure 8, described bend sensor 1 is made up of the first copper sheet 101 of a slice 0.5 millimeters thick and four first foil gauges 102 be pasted onto on described first copper sheet 101, the stickup direction of described four first foil gauges 102 is parallel to the thread take-up tension lever connecting rod holes line of centres, measuring the flexural deformation of connecting rod 14 at connecting rod holes center line connecting direction, is also the flexural deformation of connecting rod 14 direction of motion.

Further, shown in Figure 9, described twist sensors 2 is made up of the second copper sheet 201 of a slice 0.5 millimeters thick and four second foil gauges 202 be pasted onto on described second copper sheet 201, the stickup direction of described four second foil gauges 202 becomes 45o angle with the thread take-up tension lever connecting rod holes line of centres, measuring the torsional deformation of connecting rod 14 at connecting rod holes center line connecting direction, is also the torsional deformation of connecting rod 14 direction of motion.

Bend sensor 1 and twist sensors 2 are pasted onto on the two sides at 2mm thickness place, middle part of thread take-up tension lever connecting rod 14 respectively, and 2mm is the thinnest part of connecting rod 14 thickness, and the reaction of foil gauge is the sensitiveest.

Further, shown in Figure 10, described bending sensor 3 is made up of the 3rd copper sheet 301 of a slice 0.5 millimeters thick and eight the 3rd foil gauges 302 be pasted onto on described 3rd copper sheet 301, the stickup direction of four described 3rd foil gauges 302 is parallel with the vertical direction of described thread take-up tension lever vertical arm 16, measures the flexural deformation of vertical arm 16 vertical direction; The another stickup direction of four described 3rd foil gauges 302 and the vertical direction angle at 45 ° of described thread take-up tension lever vertical arm 16, measure the torsional deformation of vertical arm 16 vertical direction.

The link supporting of thread take-up tension lever is in holes, and macropore diameter is 8mm, and small aperture is 5.2mm.Relative to two supporting vertical arm and take-up arm be all take-up arm, space cantilever beam.Sewing thread is walked around from the eyelet of take-up arm, and the eyelet of take-up arm is subject to the acting force of sewing thread, and the direction of acting force is downwardly towards interior, and acting force is not orthogonal to the plane of movement of thread take-up tension lever.Shown in Fig. 2,3, sewing thread walks around eyelet, and sewing thread is by way of take-up hole pin, and the height of take-up hole pin is 3 millimeters, and therefore the acting force of sewing thread all acts on the cantilevered end of take-up arm through take-up hole pin.

The acting force of sewing thread to thread take-up tension lever is dynamic loading, and producing the reason of dynamic loading has two, and one is that the motion of four-bar mechanism rod member produces dynamic loading, especially take-up time.Two is operating paths of sewing thread is eyelets from the eyelet of shank to thread take-up tension lever, the plane of movement of this route out of plumb connecting rod; The motion of thread take-up tension lever is plane motion, and the position of thread take-up tension lever eyelet is changing always, sewing thread take-up hole pin eye in distance and contact length be 3 millimeters.The position of shank eyelet is changing equally always, and the direction that therefore sewing thread acts on the upper power of take-up hole pin is changing always, and sewing thread tightens up a little while, relax, when tightening up, power is large a little while, and time lax, power is little, magnitude of load is changing always, and the peak value of load is very large.

Sewing thread acting force acts on the end of take-up arm, and not at grade, take-up arm is connected with connecting rod through vertical arm for take-up arm and connecting rod, and vertical arm is perpendicular to the plane of movement of connecting rod.The sewing thread acting force of change presents spatial character, be exactly force direction is spatial variations.The plane of movement of dynamic loading direction out of plumb take-up arm.Take-up lever pin eye is under the effect of dynamic loading, and take-up arm overhangs downwards and reaches 0.5 millimeter.Connecting rod cross section and vertical arm cross section not only have bending distortion in addition, therefore measures thread take-up tension lever bending and distortion at the volley, with the bending and distortion on sensor measurement vertical arm and connecting rod.

Thread take-up tension lever is subject to very large dynamic loading, and the complicated also amplitude of the thread take-up tension lever vibration shape is large, and in production and application, thread take-up tension lever fractures and the crooked phenomenon of needle tracking happens occasionally.

2, the Part II measured is the vibration of measuring thread take-up tension lever each several part with three acceleration transducers, and the feature of vibration-testing signal is as follows:

1) measuring object is the accelerating curve of thread take-up tension lever, is time-domain curve;

2) signal is periodic signal;

3) use piezoelectric acceleration sensor, accelerometer be the most reliable, purposes the most extensively, the most accurate vibration transducer, the precision of acceleration test signal is high, and contained by acceleration signal, information is the abundantest.

The motion of thread take-up tension lever is based on the direction of motion of connecting rod, and the feature of thread take-up tension lever motion also exists vibration in two other direction perpendicular to direction of motion, therefore measures thread take-up tension lever acceleration, needs measurement three directions.The acceleration of thread take-up tension lever direction of motion, take-up arm end face and vertical arm side is measured with acceleration transducer.

Shown in Figure 11-14, measure the direction of motion of the first measuring point selection at thread take-up tension lever of thread take-up tension lever acceleration, the first acceleration transducer 5 is adsorbed on the flat position of take-up arm 15, but the thickness in flat direction only 2.6mm, therefore do a measurement bent plate 20.Measure bent plate 20 take-up arm 15 is clipped in the middle, clamp take-up arm 15, first acceleration transducer 5 with bolt 21, nut 22 and cushion cover 23 and be adsorbed on the side measuring bent plate 20.Connecting rod 14 is large in operative orientation rigidity, and take-up arm 15 thickness only 2.6mm in a work direction, rigidity is very little.

The travelling speed of sewing machine is within the scope of 22-90HZ, and the natural frequency of take-up arm transverse vibration (the second measuring point) is lower, and former rank natural frequency of take-up arm transverse bending vibration is close to sewing machine operating frequency, and Oscillation Amplitude is large, and thread take-up tension lever running environment is very poor.

Shown in Figure 15,16, measure the Width of the second measuring point selection at take-up arm 15 of thread take-up tension lever acceleration, described second acceleration transducer 6 is adsorbed on the end face of take-up arm 15, measures Z-direction namely perpendicular to the X-direction that take-up arm 15 moves.The vibration of Z-direction is called transverse vibration, and take-up arm 15 is semi-girder at Width, and take-up arm seems very soft under the effect of dynamic loading, and the vibratory output of end is large.

The 3rd measuring point measuring thread take-up tension lever acceleration is selected in vertical arm 16, and described 3rd acceleration transducer 7 is adsorbed on the side of described thread take-up tension lever vertical arm 16, measures the X-direction that Y-direction is moved perpendicular to thread take-up tension lever.Sewing thread acting force acts on the end of take-up arm 15, and not at grade, take-up arm 15 is connected with connecting rod 14 through vertical arm 16, and vertical arm 16 is perpendicular to the plane of movement of connecting rod 14 for take-up arm 15 and connecting rod 14.

Further, shown in Figure 17, electric bridge 401, transmitter 402, signal recognition device 403 and signal amplifier 404 is comprised in described Signal Collection and amplify device 4, described electric bridge 401 is respectively described bend sensor 1, described twist sensors 2 and described bending sensor 3 and powers, and described bend sensor 1, described twist sensors 2 are connected with described signal recognition device 403 through described transmitter 402 respectively with described bending sensor 3; Described scrambler 11 is connected with described signal recognition device 403 through described control panel 12; Described signal recognition device 403 is connected with described signal analyzer 13 through described signal amplifier 404.

The signal of described first, second, third foil gauge 102,202,302 enters described transmitter 402 respectively, and through signal recognition with after amplifying, signal exports from described Signal Collection and amplify device 404, enters described signal analyzer 13.

Described scrambler 11 and described control panel 12 form clock signal control device of the present utility model, and described scrambler 11 can adopt the scrambler of resolution 1o or 2o, and described scrambler 11 produces the horizontal ordinate of sequential and experiment curv.

On sewing machine, axle 17 turns round, gear pair 18 is placed on rear side of headstock, upper axle 17 drives scrambler 11 to turn round by gear pair 18, the encoded device 11 in angle of revolution converts angle to, and coding angle enters control panel 12 and converts digital signal to, and control panel 12 angularly sends instruction, measurement sequential is provided, the record of command control signal, output signal entering signal collection amplifier 4 and the signal analyzer 13 respectively of control panel 12, controls record and the display timing generator of each signal.

The utility model is that sewing machine provides a kind of measure measuring thread take-up tension lever bending and vibrational state, utilizes bridge-type foil gauge principle to measure the bending of thread take-up tension lever, from three orientation measurement thread take-up tension lever vibrational states.Obtaining the dynamic data of thread take-up tension lever operation by analyzing the utility model measurement, can improve for the mechanism design of high speed sewing machine and basis is provided, reduce the distortion that in motion, thread take-up tension lever is unnecessary as far as possible and bend.

Above-described embodiment, just in order to technical conceive of the present utility model and feature are described, its objective is and is one of ordinary skilled in the art can be understood content of the present utility model and implement according to this, can not limit protection domain of the present utility model with this.The change of every equivalence done by the essence of the utility model content or modification, all should be encompassed in protection domain of the present utility model.

Claims (8)

1. a thread take-up tension lever on-line vibration and flexural measurement device, it is characterized in that: comprise bend sensor (1), twist sensors (2), bending sensor (3), Signal Collection and amplify device (4), first, second, third acceleration transducer (5,6,7), first, second, third load amplifier (8,9,10), scrambler (11), control panel (12) and signal analyzer (13); Described bend sensor (1) and described twist sensors (2) are arranged on thread take-up tension lever connecting rod (14), described first acceleration transducer (5) and described second acceleration transducer (6) are separately positioned on thread take-up tension lever take-up arm (15), described bending sensor (3) and described 3rd acceleration transducer (7) are arranged in thread take-up tension lever vertical arm (16), and described scrambler (11) is arranged on the gear pair (18) of axle on sewing machine (17);

Described bend sensor (1), described twist sensors (2) are all connected with described signal analyzer (13) by described Signal Collection and amplify device (4) with described bending sensor (3); Described first, second, third acceleration transducer (5,6,7) is connected with described signal analyzer (13) respectively by the described first, second, third load amplifier (8,9,10) of correspondence; Described scrambler (11) is connected with described signal analyzer (13) by described control panel (12), and described control panel (12) is connected with described Signal Collection and amplify device (4), and described signal analyzer (13) is connected with a display screen (19).

2. thread take-up tension lever on-line vibration according to claim 1 and flexural measurement device, it is characterized in that: described bend sensor (1) is pasted onto the side at 2mm thickness place, described thread take-up tension lever connecting rod (14) middle part, described bend sensor (1) is made up of a slice first copper sheet (101) and four first foil gauges (102) be pasted onto on described first copper sheet (101), and the stickup direction of described four first foil gauges (102) is parallel to the thread take-up tension lever connecting rod holes line of centres.

3. thread take-up tension lever on-line vibration according to claim 1 and flexural measurement device, it is characterized in that: described twist sensors (2) is pasted onto the opposite side at 2mm thickness place, described thread take-up tension lever connecting rod (14) middle part, described twist sensors (2) is made up of a slice second copper sheet (201) and four second foil gauges (202) be pasted onto on described second copper sheet (201), and the stickup direction of described four second foil gauges (202) becomes 45o angle with the thread take-up tension lever connecting rod holes line of centres.

4. thread take-up tension lever on-line vibration according to claim 1 and flexural measurement device, it is characterized in that: described bending sensor (3) is pasted onto the lateral surface at 3.8mm thickness place, described thread take-up tension lever vertical arm (16) middle part, described bending sensor (3) is made up of a slice the 3rd copper sheet (301) and eight the 3rd foil gauges (302) be pasted onto on described 3rd copper sheet (301), the stickup direction of four described 3rd foil gauges (302) is parallel with the vertical direction of described thread take-up tension lever vertical arm (16), another four described stickup directions of the 3rd foil gauge (302) and the vertical direction angle at 45 ° of described thread take-up tension lever vertical arm (16).

5. thread take-up tension lever on-line vibration according to claim 1 and flexural measurement device, it is characterized in that: described first acceleration transducer (5) is adsorbed on the side that a piece is measured bent plate (20), described measurement bent plate (20) is fixed on described thread take-up tension lever take-up arm (15), described thread take-up tension lever take-up arm (15) is clipped in the middle by described measurement bent plate (20), and clamps described thread take-up tension lever take-up arm (15) by bolt (21), nut (22) and cushion cover (23).

6. thread take-up tension lever on-line vibration according to claim 1 and flexural measurement device, is characterized in that: described second acceleration transducer (6) is adsorbed on the end face of described thread take-up tension lever take-up arm (15).

7. thread take-up tension lever on-line vibration according to claim 1 and flexural measurement device, is characterized in that: described 3rd acceleration transducer (7) is adsorbed on the side of described thread take-up tension lever vertical arm (16).

8. thread take-up tension lever on-line vibration according to claim 1 and flexural measurement device, it is characterized in that: in described Signal Collection and amplify device (4), comprise electric bridge (401), transmitter (402), signal recognition device (403) and signal amplifier (404), described electric bridge (401) is respectively described bend sensor (1), described twist sensors (2) and described bending sensor (3) power supply, described bend sensor (1), described twist sensors (2) is connected with described signal recognition device (403) through described transmitter (402) respectively with described bending sensor (3), described scrambler (11) and described control panel (12) composition clock signal control device, described scrambler (11) is connected with described signal recognition device (403) through described control panel (12), described signal recognition device (403) is connected with described signal analyzer (13) through described signal amplifier (404).