CN201788095U - Reliability Test System of CNC Turret Turret with Electro-hydraulic Servo Loading Device - Google Patents

Abstract

The utility model discloses a numerical control turret head reliability test system having an electro-hydraulic servo loading device, aimed at solving a problem that the prior device cannot simulate a real cutting force to perform loading test on the numerical control turret head. The numerical control turret head reliability test system having the electro-hydraulic servo loading device is composed of a pump station, a hydraulic loading mechanism (I), a numerical control turret head control part (II) and an electro-hydraulic servo loading control part (III). The hydraulic loading mechanism (I) comprises a stress application lever (3) and an oil cylinder (16); the numerical control turret head control part (II) comprises a programmable controller (20); and the electro-hydraulic servo loading control part (III) comprises a pressure sensor (4), a displacement sensor (8) and an electro-hydraulic servo valve (17). The hydraulic loading mechanism (I) and the numerical control turret head control part (II) are both installed on a working platform (18). The electro-hydraulic servo loading control part (III) is installed on an external wall of the oil cylinder (16), and the electro-hydraulic servo loading control part (III) and the oil cylinder (16) are both connected with a pipeline of the pump station.

Description

Numerical control turret knife rest reliability test system with electro-hydraulic servo charger

Technical field

The utility model relates to a kind of reliability test system of numerically-controlled machine numerical control turret knife rest, particularly relates to a kind of numerical control turret knife rest reliability test system with electro-hydraulic servo charger.

Background technology

Fast development along with equipment manufacture, China has become the rich and influential family of numerically-controlled machine production and application, research according to investigations, the domestic numerical control lathe still has very big gap at aspects such as q﹠rs compared with developed countries, has limited to the level and the ability of China's equipment manufacture thus.Numerically-controlled slide is the key feature of numerically-controlled machine, its reliability level has key effect to the reliability raising of complete machine, reliability consideration to numerically-controlled slide need be based on fault data, but the on-the-spot tracking test of knife rest is wasted time and energy, and is difficult to obtain a large amount of fault datas in the short time again.Based on self handling characteristics of knife rest, can carry out continuous fail-test to it separately, the test efficiency height uses manpower and material resources sparingly, and this just needs a kind of reliability test system at knife rest.

The fail-test of domestic relevant numerically-controlled machine is started late, the simple numerical control turret knife rest of some functions testing table is arranged, this testing table can only carry out continuous operation test under the no-load condition to the numerical control turret, on the cutterhead of numerical control turret knife rest, increase weighting block when perhaps testing, what the weight difference tool setting dish of different cutters produced under the simulation truth lays particular stress on, even but like this, still there is a big difference for the working environment of test simulation and numerical control turret knife rest real work situation, under the real work situation, cutter is subjected to dynamic cutting force during cutting, its indirectly-acting is on the cutterhead of numerical control turret knife rest, this factor has a significant impact the life-span and the reliability of numerical control turret, and existing testing equipment all can not simulation cutting power carry out load test to the numerical control turret.This pilot system has increased the dynamic and static loading structure of the multi-angle of numerical control turret on traditional numerical control turret knife rest transposition experimental basis, has remedied the deficiency of existing testing equipment, compared with prior art, has significant creativeness and progressive.

Summary of the invention

Technical problem to be solved in the utility model is that the reliability-test equipment that has overcome present numerical control turret knife rest can not be simulated dynamic cutting force carries out load test to the numerical control turret problem, a kind of numerically-controlled machine numerical control turret knife rest reliability test system is provided, a kind of reliability test system with numerically-controlled machine numerical control turret knife rest of electro-hydraulic servo charger particularly is provided.

For solving the problems of the technologies described above, the utility model is to adopt following technical scheme to realize: described numerical control turret knife rest reliability test system with electro-hydraulic servo charger partly is made up of pumping plant, hydraulic loaded mechanism, numerical control turret knife rest control section and electro-hydraulic servo Loading Control.Described hydraulic loaded mechanism comprises boosting-rod, keeps spring, bent plate, slide plate, base, rotating shaft, rotating shaft slide plate, oil cylinder retainer, oil cylinder and worktable.

Base is installed in the right-hand member of worktable by bolt, slide plate by T shape screw retention on base, bent plate by T shape screw retention on slide plate, in the right spindle in the rotating shaft and the bent plate vertically the through hole on the installing plate be rotationally connected and then lock by means of bolt.After being rotationally connected, through hole in horizontal rotating shaft on the rotating shaft slide plate and the rotating shaft on the left rectangular slab locks by means of bolt.The oil cylinder retainer is connected on the rotating shaft slide plate by T type screw, the upper end of oil cylinder is connected with the oil cylinder retainer, being separately installed with the maintenance spring between the both sides of the lower end of oil cylinder and the oil cylinder retainer, fixedlys connected with boosting-rod one end by the pressure transducer in the electro-hydraulic servo Loading Control part in the end of the piston rod of oil cylinder lower end.

The upper end of the oil cylinder described in the technical scheme is connected with the oil cylinder retainer and is meant: a upper end cover is fixed by four double-screw bolts in the top of oil cylinder, and the upper end cover of oil cylinder top is hinged on the oil cylinder retainer by oscillating bearing.Fix a linear axis between upper end cover and oil cylinder upper surface, the axis of symmetry of linear axis is parallel with the axis of symmetry of oil cylinder piston bar.Slidely connecting box linear bearing on the linear axis, fixedlys connected in an end of box linear bearing and the end of piston rod, and the inner core of the displacement transducer in the other end of box linear bearing and the electro-hydraulic servo Loading Control part is fixedlyed connected; Described rotating shaft is formed one successively by right spindle, circular flange dish and left rectangular slab, the axis of symmetry conllinear of right spindle, circular flange dish and left rectangular slab.Be evenly equipped with four sections annular through groove that are used to pass bolt on the circular flange dish, the center of left rectangular slab is provided with a through hole, is evenly equipped with three sections annular through groove that are used to pass bolt around this through hole; Described rotating shaft slide plate is an elongated plates class formation spare.Be provided with 2 T-slots on the front end face of rotating shaft slide plate from top to bottom, the lower end of the rear end face of rotating shaft slide plate is provided with a horizontal rotating shaft, and promptly the rotational symmetry line of horizontal rotating shaft is vertical with the front and rear end of rotating shaft slide plate.Be provided with in three and the rotating shaft three sections corresponding threaded holes of annular through groove on the left rectangular slab around the horizontal rotating shaft; Described oil cylinder retainer is a strip case structure spare, promptly is made of a base plate, a top board left plate and a right plate identical with two block structures.The right plate that left plate, top board and structure are identical is fixed on the base plate front end face from left, last and right three faces, and the lower end of oil cylinder retainer is opened wide.Be evenly equipped with two on the base plate and arrange the through hole that passes bolt, the distance between 2 T-slots on distance between two exhausting holes and the rotating shaft nose face equates; Described numerical control turret knife rest control section comprises upper industrial computer, Programmable Logic Controller, solenoid directional control valve and Simulated Arbor.The up direction of Programmable Logic Controller is electrically connected with upper industrial computer.The down direction of Programmable Logic Controller is electrically connected with solenoid directional control valve with saddle controller respectively.Servo motor power supply interface on the down direction of saddle controller and the numerical control turret knife rest to be measured is electrically connected with the servomotor encoder interfaces.The P mouth of solenoid directional control valve is connected with the oil return opening pipeline with the oil-feed port of pumping plant respectively with the T mouth.The control port A mouth of solenoid directional control valve and control port B respectively with numerical control turret knife rest to be measured on locking with unclamp cylinder pipe and be connected.Simulated Arbor is installed on the cutterhead of numerical control turret knife rest to be measured; The up direction of described Programmable Logic Controller is electrically connected with upper industrial computer, and the down direction of Programmable Logic Controller is electrically connected with solenoid directional control valve with saddle controller respectively and is meant: the up direction of Programmable Logic Controller is connected with the RS-232C port serial ports of upper industrial computer by built-in RS-232C port.6 input points in the Programmable Logic Controller down direction are connected with 1 location end signal output point on the saddle controller respectively, 4 current station feedback signal output points connections are connected with 1 knife rest alerting signal output point.Also have 2 input points respectively with the numerical control turret knife rest on the sensor that unclamps be connected with the lock sensor interface.7 output points in the Programmable Logic Controller down direction respectively with saddle controller on 4 station signals, 2 mode of operation signals be electrically connected with 1 enabling signal input point.Also have 2 output points to be connected with unclamping of solenoid directional control valve with the locking power interface; Described electro-hydraulic servo Loading Control partly comprises upper industrial computer, No. 1 A/D card, No. 1 signal amplifier, servoamplifier, D/A card, No. 2 signal amplifiers, No. 2 A/D cards, pressure transducer, displacement transducer and electrohydraulic servo valves.The oil-feed port P of electrohydraulic servo valve is connected with the oil return opening pipeline with the oil-feed port of pumping plant respectively with oil return inlet T, and the control port A of electrohydraulic servo valve is connected with the upper and lower oil pocket pipeline of oil cylinder respectively with control port B.4 core electrical outlets on the electrohydraulic servo valve are connected with servoamplifier by shielding line, are electrically connected with upper industrial computer (19) through the D/A card.Displacement transducer is connected with No. 1 signal amplifier by shielding line, is electrically connected with upper industrial computer through No. 1 A/D card.Pressure transducer is connected with No. 2 signal amplifiers by shielding line, is electrically connected with upper industrial computer through No. 2 A/D cards.

Compared with prior art the beneficial effects of the utility model are:

1. the numerical control turret knife rest reliability test system with electro-hydraulic servo charger described in the utility model is compared with existing testing equipment, this pilot system is taken into account cutting force under the real work environment to this factor of material impact that numerical control turret reliability produces, hydraulic loaded mechanism and control system thereof have been increased innovatively, content of the test not only comprises the transposition of numerical control turret knife rest, the location, clamp, and added moving, static loading procedure, simulate the cutting force that the numerical control turret knife rest is subjected in the true working angles, hydraulic loaded mechanism can also carry out the adjusting of position and angle, thereby can further simulate each loading angle of numerical control turret knife rest, on multi-angle, can move it, the static loading, this pilot system has better been reduced the real work situation of numerical control turret knife rest, thereby makes the numerical control turret knife rest fault data that obtains in the test and the numerical control turret knife rest reliability level that records more true and reliable.On the other hand, hydraulic loaded mechanism can carry out the adjusting of position and angle, makes this pilot system can both carry out fail-test to the numerical control turret knife rest of different model and size, has increased the dirigibility of this pilot system.

2. when the numerical control turret knife rest reliability test system with electro-hydraulic servo charger described in the utility model carries out continuous fail-test in the laboratory, the entire test circulation is constantly carried out in an orderly manner, and the fault typing Mishap Database that the numerical control turret knife rest is taken place, gathering numerical control turret knife rest fault data with on-the-spot tracking test compares, improve test efficiency and fault collection speed, saved a large amount of financial resources, material resources and time.

Description of drawings

Below in conjunction with accompanying drawing the utility model is further described:

Fig. 1 is the front view of numerical control turret knife rest reliability test system when off working state with electro-hydraulic servo charger described in the utility model;

Fig. 2 is the left view of numerical control turret knife rest reliability test system when off working state with electro-hydraulic servo charger described in the utility model;

Fig. 3 is the axonometric projection graph of the numerical control turret knife rest reliability test system with electro-hydraulic servo charger described in the utility model when in running order;

Fig. 4 is the schematic block diagram of the structural principle of the expression numerical control turret knife rest reliability test system with electro-hydraulic servo charger described in the utility model;

Among the figure: 1. numerical control turret knife rest, 2. Simulated Arbor, 3. boosting-rod, 4. pressure transducer, 5. oscillating bearing, 6. linear axis, 7. box linear bearing, 8. displacement transducer 9. keeps spring, 10. bent plate, 11. slide plates, 12. bases, 13. rotating shaft, 14. rotating shaft slide plates, 15. oil cylinder retainers, 16. oil cylinder, 17. electrohydraulic servo valves, 18. worktable, 19. upper industrial computer, 20. Programmable Logic Controllers (PLC), 21. solenoid directional control valves, 22. saddle controller, 23.1 number A/D card, No. 24.1 signal amplifiers, 25. servoamplifiers, 26.D/A card, 27.2 number signal amplifier, No. 28.2 A/D cards, I. hydraulic loaded mechanism, II. numerical control turret knife rest control section, III. electro-hydraulic servo Loading Control part.

Embodiment

Below in conjunction with accompanying drawing the utility model is explained in detail:

Consult Fig. 3, the utility model is can not simulation cutting power carry out load test to the numerical control turret at the reliability-test equipment of existing numerically-controlled machine numerical control turret knife rest, there are very this present situation of big-difference in test simulation environment and numerical control turret knife rest real working condition, a kind of reliability test system of numerically-controlled machine numerical control turret knife rest is provided, a kind of reliability test system with numerically-controlled machine numerical control turret knife rest of electro-hydraulic servo charger particularly is provided, has realized the fail-test in the laboratory of numerically-controlled machine numerical control turret knife rest.Content of the test not only comprises the transposition test of numerical control turret knife rest, importantly can also simulation cutting power carry out dynamic and static load test to the numerical control turret, and be the dynamic and static loading of multi-angle, successfully simulated numerical control turret knife rest real work environment, and the fault typing numerical control turret knife rest Mishap Database that the numerical control turret knife rest is produced, test condition is pressed close to numerical control turret knife rest real working condition.Compare with the site test tracking test, adopt the reliability test system with numerically-controlled machine numerical control turret knife rest of electro-hydraulic servo charger provided by the utility model just can test, significantly reduced and carried out at the scene spent manpower and materials and the time of numerical control turret knife rest test the numerical control turret in the laboratory.Compare with existing reliability-test equipment, this pilot system is taken into account by this key factor of dynamic and static cutting force of multi-angle during with numerical control turret knife rest real work, and simulated, better reduced numerical control turret knife rest real work environment, thereby make the fault data of numerical control turret knife rest of collection more genuine and believable, the reliability level of the numerical control turret knife rest that records is more convincing.Reliability test system with numerically-controlled machine numerical control turret knife rest of electro-hydraulic servo charger is made up of pumping plant, hydraulic loaded mechanism I, numerical control turret knife rest control section II and electro-hydraulic servo Loading Control part III.Hydraulic loaded mechanism I and numerical control turret knife rest control section II (critical piece) are directly installed on the two ends of worktable 18.Electro-hydraulic servo Loading Control part III (critical piece) is installed on the outer wall of the oil cylinder 16 in the hydraulic loaded mechanism I, being connected into and out of the hydraulic fluid port pipeline of one end of electro-hydraulic servo Loading Control part III and oil cylinder 16, the other end of electro-hydraulic servo Loading Control part III is connected with the pumping plant pipeline.

Consult Fig. 1 and Fig. 2, hydraulic loaded mechanism I comprises boosting-rod 3, oscillating bearing 5, linear axis 6, box linear bearing 7, keeps the support member of spring 9, bent plate 10, slide plate 11, base 12, rotating shaft 13, rotating shaft slide plate 14, oil cylinder retainer 15, oil cylinder 16, worktable 18, bolt and oscillating bearing.

Bent plate 10 includes mutually perpendicular installation base plate, vertical installing plate and a pair of reinforcement gusset between the two, base plate is installed and vertically all is evenly equipped with the through hole that passes T type screw/bolt on the installing plate, vertically the center of the uniform through hole that passes bolt is provided with the through hole that is equipped with rotating shaft 13 on the installing plate.

Slide plate 11 is rectangular plate structure spares, be provided with on the last workplace of slide plate 11 two with the parallel T-slot of slide plate 11 vertical line of symmetries, its four jiaos places are provided with the through hole that T type screw is passed in last workplace vertical being used to, and the following workplace of slide plate 11 is shiny surfaces parallel with last workplace.

Base 12 is box structures of a rectangular parallelepiped formula, the last workplace of base 12 is provided with 2 T-slots that are parallel to each other from left to right, the following workplace of base 12 is provided with the chimb that stretches out to forward and backward both sides from left to right, is evenly equipped with the through hole that can vertically pass bolt on the chimb.

Rotating shaft 13 is formed (making) one successively by right spindle, circular flange dish and left rectangular slab, and the axis of symmetry conllinear of three parts.Be evenly equipped with on the circular flange dish with bent plate 10 in vertical uniform corresponding four sections annular through groove of through hole on the installing plate.The center of left side rectangular slab is provided with a through hole, is provided with three sections annular through groove that are used to pass bolt around this through hole.

Rotating shaft slide plate 14 is elongated plates class formation spares, be provided with 2 T-slots from top to bottom on preceding (right side) end face of rotating shaft slide plate 14, the lower end of back (left side) end face of rotating shaft slide plate 14 is provided with a horizontal rotating shaft, preceding (right side), back (left side) end face of being the rotational symmetry line of horizontal rotating shaft and rotating shaft slide plate 14 are vertical, three sections corresponding threaded holes of annular through groove on the left rectangular slab in being provided with three and rotating shaft 13 around the horizontal rotating shaft.

Oil cylinder retainer 15 is strip case structure spares, promptly constitute by a base plate, a top board left and right side plate identical with two block structures, the identical right plate of left plate, top board and structure from a left side, go up, right three faces are fixed on before the base plate on (right side) end face, the lower end of oil cylinder retainer 15 is opened wide, be evenly equipped with two on the base plate and arrange the through hole that (4 or 6) are used to pass bolt, the distance between 2 T-slots before distance between two exhausting holes and the rotating shaft slide plate 14 on (right side) end faces equates.

Oil cylinder 16 is selected double piston-rod and single piston-type hydro compressing cylinder for use, double piston-rod stretches out from the upper and lower end of oil cylinder 16 respectively, a upper end cover is fixed by four double-screw bolts in the top of (stretching out a piston rod) upper surface of oil cylinder 16, and oil cylinder 16 is fixedly connected on the lower surface of top board in the oil cylinder retainer 15 with the support member of oscillating bearing by this upper end cover, oscillating bearing 5.Fix a linear axis 6 between (stretching out a piston rod) upper surface of upper end cover and oil cylinder 16, the axis of symmetry of linear axis 6 is parallel with the axis of symmetry of the piston rod of oil cylinder 16.Being set with the box linear bearing 7 that can slide on linear axis 6 on the linear axis 6, fixedlys connected in an end of box linear bearing 7 and the end of piston rod, and promptly box linear bearing 7 can slide with upper and lower the moving on linear axis 6 of piston rod.The inner core of the displacement transducer 8 in the other end of box linear bearing 7 and the electro-hydraulic servo Loading Control part (III) is connected, and also along with mobile, displacement transducer 8 just can record the displacement of piston rod to the inner core of displacement transducer 8 when piston rod moves.

Worktable 18 is box structures, can adopt shaped steel to be welded into skeleton earlier, then and upper surface cover upper steel plate, upper surface is the installed surface of installation hydraulic loaded mechanism's I and numerical control turret knife rest 1 to be measured, the bottom surface of worktable 18 is provided with height adjustable installation footing for four jiaos.

Base 12 is installed in the right-hand member of worktable 18 by bolt, and on workplace on the base 12,2 T-slots on the slide plate 11 are vertical with 2 T-slots on the base 12 by T shape screw retention for slide plate 11.Installation base plate in the bent plate 10 passes through T shape screw retention on slide plate 11, right spindle in the rotating shaft 13 inserts in the bent plate 10 to become to be rotationally connected in the through hole on the vertical installing plate, and circular flange dish in the rotating shaft 13 and the vertical installing plate in the bent plate 10 are contacted, rotating shaft 13 is adjusted the back with respect to the vertical installing plate position in the bent plate 10 and is adopted bolt with both fixedly connected (locking), adjusting can be rotated in the position of rotating shaft 13 vertical installing plate in bent plate 10, after position adjustments is good fixedly connected again (locking).The horizontal rotating shaft of rotating shaft slide plate 14 is packed into and is become to be rotationally connected in the through hole of left rectangular slab in the rotating shaft 13, relends after adjust the position of rotating shaft slide plate 14 to help bolt both fixedly connected (locking) with rotating shaft slide plate 14 and rotating shaft 13.Oil cylinder retainer 15 is connected in by T type screw on preceding (right side) end face of rotating shaft slide plate 14, and oil cylinder 16, oscillating bearing 5, linear axis 6, box linear bearing 7, displacement transducer 8 these assemblies are fixedly connected on the lower surface of the top board in the oil cylinder retainer 15 by means of the support connecting piece (transverse axis and two bearing spiders) of oscillating bearing.Maintenance spring 9 is installed between the left and right side plate of the both sides of the lower end of oil cylinder 16 and oil cylinder retainer 15, and keeping the effect of spring 9 is that the position of oil cylinder 16 and direction are remained unchanged.Fixedly connected with an end of pressure transducer 4 in the end of the piston rod of oil cylinder 16 lower ends, the other end of pressure transducer 4 is fixedlyed connected with boosting-rod 3 one ends, and the other end of boosting-rod 3 is arranged to the concave surface that the recessed inwards sphere with on the Simulated Arbor 2 matches.

Relate to 3 kinds in the structural design of hydraulic loaded mechanism I and move and 2 kinds of rotations, these structural designs can make the position of oil cylinder 16 and angle regulate within the specific limits.Advantage has two: one, and the size and Orientation of numerical control turret knife rest 1 suffered dynamic load power can be different when the real working condition bottom tool carried out the cutting of different situations, therefore the position and the angle of oil cylinder 16 can be regulated within the specific limits, just can simulate the various true loading angles of numerical control turret knife rest, on each loading angle, can carry out dynamic and static loading it; The 2nd, by adjusting to oil cylinder 16 positions and angle, can be to different model, the numerical control turret knife rest of different size carries out load test, has increased dirigibility and the versatility with numerical control turret knife rest reliability test system of electro-hydraulic servo charger described in the utility model.

Numerical control turret knife rest control section II comprises upper industrial computer 19, Programmable Logic Controller (PLC) 20, solenoid directional control valve 21 and (being installed on the numerical control turret knife rest 1 to be measured) Simulated Arbor 2.

The up direction of Programmable Logic Controller 20 is electrically connected with upper industrial computer 19, the down direction of Programmable Logic Controller 20 is electrically connected with solenoid directional control valve 21 with the up direction of saddle controller 22 respectively, servo motor power supply interface on the down direction of saddle controller 22 and the numerical control turret knife rest 1 to be measured is electrically connected with the servomotor encoder interfaces, the P mouth of solenoid directional control valve 21 is connected the control port A mouth of solenoid directional control valve 21 respectively with the T mouth with the oil return opening pipeline with the oil-feed port of pumping plant, control port B mouth respectively with numerical control turret knife rest 1 to be measured on locking with unclamp cylinder pipe and be connected.Simulated Arbor 2 is installed on the cutterhead of numerical control turret knife rest 1 to be measured, numerical control turret knife rest 1 to be measured is fixedly mounted on the left end of worktable 18, the axis of rotation space parallel of the axis of rotation of cutterhead and hydraulic loaded mechanism I shaft 13 in the numerical control turret knife rest 1 to be measured by parts such as bolts.

More particularly, Programmable Logic Controller 20 is that the employing model is the Omron Programmable Logic Controller of CMP2A-30CDR-D among the embodiment, direct current 24V power supply, 18 direct current input points are arranged, 12 direct current output points, Programmable Logic Controller 20 up directions are connected with the RS-232C port of upper industrial computer 19 by built-in RS-232C port and carry out serial communication, 6 input points are connected with 1 location end signal output point on the saddle controller 22 respectively in Programmable Logic Controller 20 down directions, 4 current station feedback signal output points connect, 1 numerical control turret alerting signal output point connects, also have 2 input points respectively with the numerical control turret knife rest on the sensor that unclamps be connected with the lock sensor interface.7 output points of Programmable Logic Controller 20 down directions respectively with saddle controller 22 on 4 station signals, 2 mode of operation signals be connected with 1 enabling signal input point, also have 2 output points to be electrically connected with the power interface that unclamps, locks of solenoid directional control valve 21.

Saddle controller 22 be with numerical control turret knife rest 1 to be measured in Mitsubishi's model of servomotor coupling be the servoamplifier of MR-J3-40A-RJ070, ingredient for numerical control turret knife rest 1 to be measured, servo motor power supply interface in the two-phase alternating current 220V power supply, saddle controller 22 down directions and numerical control turret knife rest and the servomotor encoder interfaces is supporting is electrically connected.

Upper industrial computer 19 control interfaces are to be made by VB, behind the station of selecting the mode of operation of numerical control turret knife rest 1 on the control interface and needing, with Programmable Logic Controller 20 serial communications, 21 actions of Programmable Logic Controller 20 first output current control solenoid directional control valves, control numerical control turret knife rest 1 cutterhead unclamps, upper industrial computer 19 receives to unclamp determines signal output services mode signal afterwards, station signal and enabling signal are given saddle controller 22, saddle controller 22 control numerical control turret knife rests 1 forward required station to, saddle controller 22 feeds back to location end signal and current station signal and gives Programmable Logic Controller 20 afterwards, then feed back alerting signal as fault, output current control solenoid directional control valve 21 moved after Programmable Logic Controller 20 received location end signal and current station signal, the cutterhead locking of control numerical control turret knife rest, receive locking and determine that feeding back to 19, tool changing of upper industrial computer together with the current station signal behind the signal finishes.

The true knife bar dimensioned of Simulated Arbor 2 simulations; different is that external part is processed into sphere; purpose can withhold on the sphere of Simulated Arbor 2 one ends the concave surface of boosting-rod 3 when being loading; the side force that piston rod bore when this design had reduced oil cylinder 16 dynamic load has greatly well been protected oil cylinder 16.

Electro-hydraulic servo Loading Control part III comprises 19, No. 1 23, No. 1 signal amplifiers 24 of A/D card of upper industrial computer (with shared same the upper industrial computer of numerical control turret knife rest control section II), servoamplifier 25,26, No. 2 signal amplifiers of D/A card 27, No. 2 A/D cards 28, pressure transducer 4, displacement transducer 8 and electrohydraulic servo valves 17.Electrohydraulic servo valve 17 is installed on the outer wall of cylinder block of oil cylinder 16.

The oil-feed port P of electrohydraulic servo valve 17 is connected with the oil return opening pipeline with the oil-feed port of pumping plant respectively with oil return inlet T, the control port A of electrohydraulic servo valve 17 is connected with the upper and lower oil pocket pipeline of oil cylinder (16) respectively with control port B, 4 core electrical outlets on the electrohydraulic servo valve 17 are connected with servoamplifier 25 by shielding line, are electrically connected with upper industrial computer 19 through D/A card 26; Displacement transducer 8 is connected with No. 1 signal amplifier 24 by shielding line, is electrically connected with upper industrial computer 19 through No. 1 A/D card 23; Pressure transducer 4 is connected with No. 2 signal amplifiers 27 by shielding line, is electrically connected with upper industrial computer 19 through No. 2 A/D cards 28.

Electrohydraulic servo valve 17 among the embodiment adopts U.S. MOOG G761 series mechanical reaction type four-way electrohydraulic servo valves, dynamic response performance height, the load flow of the change control valve mouth of the current signal by spool.The oil-feed port P of electrohydraulic servo valve 17 and oil return inlet T are respectively at being connected with the oil return opening pipeline with the oil-feed port of pumping plant, and control port A and control port B connect with the last lower oil cavitie of oil cylinder respectively.The 4 core electrical outlets that have standard on the electrohydraulic servo valve 17, by being furnished with model is that the shielding line of the cable plug of MS3106F14S2S is connected with the servoamplifier 25 of electrohydraulic servo valve 17, servoamplifier 25 adopts the alternating current 220V power supply, is connected on the upper industrial computer 19 through D/A card 26.Pressure transducer 4 is connected with No. 2 signal amplifiers 27 by 4 core shielding lines, be connected on the upper industrial computer 19 through No. 2 A/D cards 28, displacement transducer 8 is connected with No. 1 signal amplifier 24 by 4 core shielding lines, is connected on the upper industrial computer 19 through No. 1 A/D card 23.

Upper industrial computer 19 control programs are also made by VB, and whole electro-hydraulic servo Loading Control part III is a close loop control circuit, can form closed loop by Displacement Feedback or pressure feedback.And merge with numerical control turret knife rest control section II, form a complete numerically-controlled machine numerical control turret knife rest fail-test control system.After power supply, pumping plant were opened, upper industrial computer 19 moved down by displacement closed-loop control piston rod earlier.Boosting-rod 3 front ends are withheld on Simulated Arbor 2, transfer pressure closed loop control afterwards to, upper industrial computer 19 sends 26 conversions of command signal process D/A card according to required loading force, vibration frequency and loading waveform and passes to servoamplifier 25, change the opening amount of current signal control electrohydraulic servo valve 17 after conditioning into, control oil cylinder 16 loads.At this moment, pressure transducer 4 imports upper industrial computer 19 into after Simulated Arbor 2 stressed fed back the amplification through No. 2 signal amplifiers 27, No. 2 A/D cards 28 conversions, through a series of comparison and conditioning, draws deviation signal.This deviation signal is through 26 conversions of D/A card, be input to electrohydraulic servo valve 17 after servoamplifier 25 conditionings, make electrohydraulic servo valve 17 produce the load differential pressure action on the piston of oil cylinder 16, pressure is changed to the direction that reduces error, equal until pressure till the value of command signal defined.

Pumping plant unclamps or locks and the oil cylinder 16 that is used to load provides pressure oil for numerical control turret knife rest 1, and the oil pressure requirement can satisfy Simulated Arbor 2 and bear maximum cutting force the time.

Consult Fig. 3, provided the synoptic diagram when carrying out load test among the figure, Mo Ni cutting force is selected the size and the angle of good loading force at first as required, adjust hydraulic loaded mechanism I then and determined the position and the angle of oil cylinder, the axis of boosting-rod 3 can be registered on the sphere of Simulated Arbor 2, and boosting-rod 3 one is can push up on the Simulated Arbor 2 in the stroke range of oil cylinder 16, the 2nd, after loading end boosting-rod 3 is return original position, cutterhead on the numerical control turret knife rest 1 can freely not rotate and interfere with boosting-rod 3, adjusts the back locking that finishes.Owing to keep the position and the direction of the effect oil cylinder 16 of spring 9 to remain unchanged.Power-on, pumping plant, 1 transposition of numerical control turret knife rest control section II control numerical control turret knife rest, the location, clamp, 16 actions of the oil cylinder of electro-hydraulic servo Loading Control part III control afterwards, piston rod drives boosting-rod 3 and moves to Simulated Arbor 2 spheres, the position of piston rod is by recording with the synchronous displacement transducer 8 of piston rod of installing on the oil cylinder 16, boosting-rod 3 slows down and withholds on the sphere of Simulated Arbor 2, afterwards according to given loading force, vibration frequency, load waveform and carry out dynamic load, the pressure transducer 4 feedback force signals of boosting-rod 3 upper ends are given upper industrial computer 19, whole electro-hydraulic servo Loading Control part III forms the closed-loop control of displacement or pressure, after loading end, piston rod is return original position, and the cutterhead of numerical control turret knife rest 1 is free to rotate again.Simulate other angle load test if desired, only need regulate load maintainer, adjust the loading angle that needs after, load maintainer locking just can be continued to load.

Consult Fig. 4, the expression control flow with numerical control turret knife rest reliability test system of electro-hydraulic servo charger described in the utility model among the figure.

Numerical control turret knife rest control section II

The control program of numerical control turret knife rest 1 enrolls Programmable Logic Controller 20 in advance, upper industrial computer 19 and Programmable Logic Controller 20 serial communications control saddle controller 22 and solenoid directional control valve 21, whole holding functions in the time of can realizing numerical control turret knife rest 1 real work, also can make numerical control turret knife rest 1 carry out the location and the clamping of any station continuously, the probability that navigates to each station is identical, and this function is used for numerical control turret 1 is carried out long run test.19 pairs of current station of upper industrial computer, duration of test runs, the record automatically such as location number of times of locating number of times and each station altogether, be presented on the interface of upper industrial computer 19, be convenient to the experimenter and understand the test progress, and the fault typing Mishap Database that numerical control turret knife rest 1 is taken place in process of the test.

Electro-hydraulic servo Loading Control part III

Behind numerical control turret knife rest 1 positioning and locking, upper industrial computer 19 detects the locking feedback signal and just begins loading procedure, sending control signal earlier passes to electrohydraulic servo valve 17 control piston bars through D/A card 26 conversion and moves downward, the displacement transducer of installing on the hydraulic loaded mechanism I 8 amplifies the electric signal that produces through No. 1 signal amplifier 24 and No. 1 A/D card 23 is passed to upper industrial computer 19 after changing, and by the displacement closed-loop control that is made of displacement transducer 8 boosting-rod 3 is withheld on Simulated Arbor 2.Transfer pressure closed loop control to by the displacement closed-loop control afterwards, upper industrial computer 19 sends control signal and passes to electrohydraulic servo valve 17 according to given loading parameters control oil cylinder 16 loadings through 26 conversions of D/A card, the pressure transducer of installing on the hydraulic loaded mechanism I 4 amplifies the electric signal that produces through No. 2 signal amplifiers 27 and No. 2 A/D cards 28 are passed to upper industrial computer 19 after changing, form closed-loop control on the one hand, on the other hand with the size of pressure, waveform, frequencies etc. are presented on the interface of upper industrial computer 19, and the experimenter can select and controls according to testing requirements.

Described in the utility model have the numerical control turret knife rest reliability test system of electro-hydraulic servo charger when numerical control turret 1 is carried out continuous fail-test, Mo Ni cutting situation as required, set parameters such as loading force, vibration frequency, loading waveform, load time, the servo loading of the unclamping of numerical control turret knife rest 1, rotation, location, locking and oil cylinder 16 just can move automatically.After on-test, upper industrial computer 19 control numerical control turret knife rests 1 random position is to any station, after the clamping, upper industrial computer 19 continues 1 loading of 16 pairs of numerical control turrets of control oil cylinder after receiving and clamping feedback signal, after loading procedure finishes, piston rod is return, continuation control numerical control turret knife rest 1 navigated to next one station at random after upper industrial computer 19 received displacement transducer 8 feedback signals, after the clamping, continue loading procedure again, under the automatic control and monitoring of upper industrial computer 19, the entire test circulation is constantly carried out in an orderly manner, improve test efficiency greatly, shortened the fault collection time, saved manpower and materials.

Embodiment described in the utility model can understand and use the utility model for the ease of these those skilled in the art, just a kind of preferred embodiment of the utility model, or perhaps a kind of more specific technical scheme, it only is applicable to the different model in the certain limit, the fail-test of the numerical control turret knife rest 1 of different size, different model outside the scope, the fail-test of the numerical control turret knife rest 1 of different size, basic technical scheme is constant, but the specifications and models of its used parts will change thereupon, as pumping plant, oil cylinder 16, electrohydraulic servo valve 17, the selection of standard components such as pressure transducer 4 and displacement transducer 8 is so the utility model is not limited to the description of this a kind of more specific technical scheme of embodiment.If relevant technician make under the situation of adhering to the utility model basic technical scheme that the equivalent structure that does not need through creative work changes or various modification all in protection domain of the present utility model.

Claims (8)

1. A CNC turret tool post reliability test system with an electro-hydraulic servo loading device, which consists of a pump station, a hydraulic loading mechanism (I), a CNC turret tool post control part (II) and an electro-hydraulic servo loading control part ( Ⅲ) Composition, characterized in that the hydraulic loading mechanism (I) includes a booster rod (3), a holding spring (9), a bent plate (10), a slide plate (11), a base (12), a rotating shaft (13 ), rotating shaft slide plate (14), oil cylinder cage (15), oil cylinder (16) and workbench (18); Base (12) is fixedly installed on the right end of workbench (18) by bolt, and slide plate (11) is fixed on the base (12) by T-shaped screw, and bent plate (10) is fixed on the slide plate (11) by T-shaped screw, The right-hand shaft in the rotating shaft (13) and the through hole on the vertical mounting plate in the bent plate (10) are rotatably connected and locked by means of bolts, and the horizontal rotating shaft on the rotating shaft slide plate (14) is connected with the left rectangular plate in the rotating shaft (13). After the through hole on the top is rotated and connected, it is locked by means of bolts. The oil cylinder cage (15) is fixedly connected on the rotating shaft slide plate (14) by T-shaped screws, and the upper end of the oil cylinder (16) is connected with the oil cylinder cage (15). Retaining springs (9) are respectively installed between the two sides of the lower end of 16) and the cylinder cage (15), and the end of the piston rod at the lower end of the oil cylinder (16) loads the pressure sensor in the control part (Ⅲ) through the electro-hydraulic servo (4) is fixedly connected with one end of the booster rod (3). 2. according to the numerical control turret tool rest reliability test system with electro-hydraulic servo loading device according to claim 1, it is characterized in that, the upper end of described oil cylinder (16) is connected with oil cylinder cage (15) and refers to: An upper end cover is fixed on the top of the oil cylinder (16) by four studs, and the upper end cover above the oil cylinder (16) is hinged on the oil cylinder cage (15) through a joint bearing (5). A linear shaft (6) is fixed between them, the symmetrical axis of the linear shaft (6) is parallel to the symmetrical axis of the piston rod of the oil cylinder (16), and a box-type linear bearing (7) is slidably connected to the linear shaft (6). One end of the bearing (7) is fixedly connected to the end of the piston rod, and the other end of the box-type linear bearing (7) is fixedly connected to the inner core of the displacement sensor (8) in the electro-hydraulic servo loading control part (Ⅲ). 3. according to the numerical control turret tool rest reliability test system with electro-hydraulic servo loading device according to claim 1, it is characterized in that, described rotating shaft (13) is made of right rotating shaft, circular flange and left rectangular The plates are integrated in sequence, the symmetry axes of the right shaft, the circular flange and the left rectangular plate are collinear, and the circular flange is evenly distributed with four sections of annular through grooves for passing through the bolts, and the center of the left rectangular plate is set There is a through hole, and three sections of annular through grooves for passing bolts are evenly distributed around the through hole. 4. according to the numerically controlled turret tool rest reliability test system with electro-hydraulic servo loading device according to claim 1, it is characterized in that, described rotating shaft slide plate (14) is a strip-shaped plate structure, and rotating shaft slide plate The front end face of (14) is provided with 2 T-shaped grooves from top to bottom, and the lower end of the rear end face of rotating shaft slide plate (14) is provided with a horizontal rotating shaft, and the axis symmetry line of the horizontal rotating shaft and the preceding, The rear end face is vertical, and there are three threaded holes corresponding to the three sections of circular grooves on the left rectangular plate in the rotating shaft (13) around the horizontal rotating shaft. 5. according to the numerical control turret tool rest reliability test system with electro-hydraulic servo loading device according to claim 1, it is characterized in that, described oil cylinder cage (15) is a long strip box-type structure, i.e. It consists of a bottom plate, a top plate and two left and right plates with the same structure. The left plate, top plate and right plate with the same structure are fixed on the front end of the bottom plate from the left, top and right sides. The cylinder cage The lower end of (15) is open, and two rows of through holes passing through bolts are evenly distributed on the base plate, and the distance between the two rows of through holes is the distance between the two T-shaped grooves on the front end face of the rotating shaft slide plate (14). equal. 6. The numerically controlled turret tool post reliability test system with electro-hydraulic servo loading device according to claim 1, characterized in that, the described numerically controlled turret tool post control part (II) includes a host industrial computer (19) , a programmable controller (20), an electromagnetic reversing valve (21) and an analog knife rod (2); The up direction of the programmable controller (20) is electrically connected with the host industrial computer (19), and the down direction of the programmable controller (20) is electrically connected with the tool rest controller (22) and the electromagnetic reversing valve (21) respectively, The downward direction of the tool post controller (22) is electrically connected with the servo motor power interface on the CNC turret tool post (1) to be tested and the servo motor encoder interface, and the P port and the T port of the electromagnetic reversing valve (21) are respectively It is connected with the oil supply port and the oil return port pipeline of the pump station, and the control oil port A and control oil port B of the electromagnetic reversing valve (21) are respectively connected with the locking and locking ports on the CNC turret tool rest (1) to be tested. Loosen the pipeline connection of the oil cylinder, install and clamp the simulated cutter bar (2) on the cutter head of the CNC turret tool holder (1) to be tested. 7. according to the numerical control turret tool rest reliability test system with electro-hydraulic servo loading device according to claim 6, it is characterized in that, the upward direction of described programmable logic controller (20) and upper industrial computer (19) Electrically connected, the downward direction of the programmable controller (20) is electrically connected with the knife rest controller (22) and the electromagnetic reversing valve (21) respectively and refers to: The upstream direction of the programmable controller (20) is connected with the serial port of the RS-232C port of the upper industrial computer (19) through the built-in RS-232C port, and the 6 input points in the downstream direction of the programmable controller (20) are respectively connected to the On the frame controller (22), one output point of positioning end signal is connected, four current station feedback signal output points are connected to one tool post alarm signal output point, and two input points are respectively connected to the CNC turret tool post The loosening sensor on (1) is connected to the interface of the locking sensor; the 7 output points in the downward direction of the programmable controller (20) are respectively connected with 4 station signals and 2 working modes on the tool post controller (22) The signal is electrically connected to one start signal input point, and two output points are also connected to the loosening and locking power interface of the electromagnetic reversing valve (21). 8. According to the numerical control turret tool post reliability test system with electro-hydraulic servo loading device according to claim 1 or 6, it is characterized in that, the described electro-hydraulic servo loading control part (Ⅲ) comprises a host industrial computer (19 ), No. 1 A/D card (23), No. 1 signal amplifier (24), servo amplifier (25), D/A card (26), No. 2 signal amplifier (27), No. 2 A/D card (28 ), pressure sensor (4), displacement sensor (8) and electro-hydraulic servo valve (17); The oil supply port P and the oil return port T of the electro-hydraulic servo valve (17) are respectively connected with the oil supply port and the oil return port pipeline of the pump station, and the control oil port A and control oil port B of the electro-hydraulic servo valve (17) They are respectively connected to the upper and lower oil chamber pipelines of the oil cylinder (16), and the 4-core electrical socket on the electro-hydraulic servo valve (17) is connected to the servo amplifier (25) through a shielded wire, and connected to the upper position via the D/A card (26). The industrial computer (19) is electrically connected, the displacement sensor (8) is connected to the No. 1 signal amplifier (24) through the shielded wire, and is electrically connected to the upper industrial computer (19) through the No. 1 A/D card (23), and the pressure sensor (4 ) is connected to the No. 2 signal amplifier (27) through the shielded wire, and is electrically connected to the upper industrial computer (19) through the No. 2 A/D card (28).

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