CN211966527U - Ball screw pair stop ring assembly and gap detection device for automatic parking of automobile - Google Patents

Abstract

The utility model discloses an automatic parking of car is with vice retaining ring assembly of ball screw and clearance detection device, include: the device comprises a base plate, a screw rod and nut relative position detection station, a stop ring feeding and mounting station and a gap detection station are arranged on the base plate, and a rotating motor is arranged on the base plate; the rotary motor drives the station plate to rotate, any ball screw pair installation tool provided with the ball screw pair sequentially passes through the screw nut relative position detection station, the stop ring feeding and installation station and the gap detection station, and the screw nut relative position detection station, the stop ring feeding and installation station and the gap detection station are respectively provided with a screw nut relative position detection device, a stop ring feeding and installation device and a gap detection device. The utility model discloses can convenient and fast find qualified mounted position, labour saving and time saving guarantees that retaining ring and installation clearance are in qualified within range, the accurate measurement clearance value simultaneously.

Description

Ball screw pair stop ring assembly and gap detection device for automatic parking of automobile

Technical Field

The utility model relates to the technical field of ball screw pair detection for automatic parking of automobiles, in particular to a ball screw pair stop ring assembly and gap detection device for automatic parking of automobiles; the assembling device can realize quick and accurate installation of the ball screw pair stop ring, and directly measure and store the gap value in the installation process.

Background

The ball screw pair is the most frequently used transmission element on tool machinery and precision machinery, the main function of the ball screw pair is to convert rotary motion into linear motion or convert torque into axial repeated acting force, and the ball screw pair has the characteristics of high precision, reversibility and high efficiency, and has very small friction resistance, so that the small precision ball screw pair is widely applied as a core element of an automatic parking part of an automobile.

The stop ring part has the effects that the position of one end of the nut is stopped, the overtravel of the nut is avoided, the whole ball screw pair is caused to lose efficacy, the fit clearance between the stop ring and the nut is controlled, the service life and the working principle of the ball screw pair for automatically parking the automobile are directly related, and the stop ring part is an important index for judging whether a product is qualified or not, so whether the stop ring can be rapidly and accurately assembled in the production process or not is judged, and the production efficiency and the part production cost of the ball screw pair are directly influenced.

The screw rod of the ball screw pair is provided with 6 directions (6 equally divided splines), namely the directions of 6 protruding points, and the inner hole of the stop ring is provided with 12 directions (12 equally divided splines), so that 12 positions of the stop ring and the screw rod can be adjusted, and the clearance between the stop ring and the screw nut changes by 0.3mm when the stop ring and the screw rod rotate by one matched spline tooth; according to design requirements, the fit clearance of the stop ring and the nut is 0.4 +/-0.2 mm, so that only 2 fit positions in the whole circumferential direction of the pair of parts can meet the clearance requirement, and how to realize quick and accurate assembly of the stop ring becomes one of the difficult problems in the attack and the trouble of the whole automatic assembly line.

SUMMERY OF THE UTILITY MODEL

To the problem, the utility model aims to provide an automatic ball screw that parks in of car is vice retaining ring assembly and clearance detection device, it can convenient and fast find qualified mounted position, and labour saving and time saving guarantees that retaining ring and installation clearance are in qualified scope, the accurate measurement clearance value simultaneously.

The invention purpose of the utility model can be realized by the following technical scheme:

automatic automobile parking is with vice retaining ring assembly of ball screw and clearance detection device includes:

the device comprises a base plate, a screw rod and nut relative position detection station, a stop ring feeding and mounting station and a gap detection station, wherein the base plate is circumferentially provided with the screw rod and nut relative position detection station, the stop ring feeding and mounting station and the gap detection station;

a rotating electrical machine mounted on the base plate;

the working position plate is driven to rotate by the rotating motor and drives any ball screw pair mounting tool provided with the ball screw pair to sequentially pass through the screw nut relative position detection station, the stop ring feeding and mounting station and the gap detection station;

the screw rod and nut relative position detection device is arranged on the base plate and is used for detecting the relative position of a screw rod and a nut on a ball screw pair assembled on any ball screw pair installation tool and entering the screw rod and nut relative position detection station;

the stop ring feeding and mounting device is arranged on the bottom plate and is used for axially mounting a stop ring on a screw rod of a ball screw pair entering the stop ring feeding and mounting station;

and the gap detection device is arranged on the bottom plate and is used for detecting the gap between a nut and a stop ring in a ball screw pair which enters the gap detection station and is provided with the stop ring.

In a preferred embodiment of the present invention, the screw nut relative position detecting device includes:

a detection device fixing bracket mounted on the base plate;

the detection device linear guide rail is arranged on the detection device fixing support;

a screw rod and nut relative position detection mounting plate arranged on a slide block of the linear guide rail of the detection device;

the screw rod and nut relative position detection and driving cylinder is arranged on the detection device fixing support, the screw rod and nut relative position detection and mounting plate is fixedly arranged on a piston rod of the screw rod and nut relative position detection and driving cylinder and is driven by the screw rod and nut relative position detection and driving cylinder to move up and down along the linear guide rail;

the lead screw spherical surface limiting tool is arranged on the lead screw nut relative position detection mounting plate;

and the distance measuring resistance ruler is arranged on the bottom surface of the spherical surface limiting tool of the screw rod and extends downwards.

In a preferred embodiment of the present invention, the stop ring loading and mounting device includes:

a snap ring conveying mechanism mounted on the base plate, the snap ring conveying mechanism being configured to convey a snap ring;

a stop ring loading bracket mounted on the base plate;

the stop ring feeding vertical linear guide rail is arranged on the stop ring feeding support;

the feeding mechanical arm vertical support is arranged on a sliding block of the stopping ring feeding vertical linear guide rail;

a stop ring feeding vertical driving motor and a stop ring feeding vertical screw nut mechanism which are arranged on the stop ring feeding support, wherein an output shaft of the stop ring feeding vertical driving motor is in driving connection with a screw rod in the stop ring feeding vertical screw nut mechanism, a nut in the stop ring feeding vertical screw nut mechanism is connected with a slide block of a stop ring feeding vertical linear guide rail, the stop ring feeding vertical driving motor drives the screw rod in the stop ring feeding vertical screw nut mechanism to rotate, and the rotating screw rod drives the feeding manipulator vertical support to move up and down along the stop ring feeding vertical linear guide rail through the nut in the stop ring feeding vertical screw nut mechanism;

the feeding mechanical arm horizontal support is arranged on the feeding mechanical arm vertical support;

a stop ring feeding horizontal linear guide rail arranged on the horizontal bracket of the feeding manipulator;

the clamping cylinder bracket is arranged on a sliding block of the stop ring feeding horizontal linear guide rail;

the output shaft of the stop ring feeding horizontal driving motor is in driving connection with a screw rod in the stop ring feeding horizontal screw rod nut mechanism, a nut in the stop ring feeding horizontal screw rod nut mechanism is connected with the clamping cylinder support, the stop ring feeding horizontal driving motor drives the screw rod in the stop ring feeding horizontal screw rod nut mechanism to rotate, and the rotating screw rod drives the clamping cylinder support to move back and forth along the stop ring feeding horizontal linear guide rail through the nut in the stop ring feeding horizontal screw rod nut mechanism;

the clamping cylinder and the stop ring feeding manipulator are mounted on the clamping cylinder support, the clamping cylinder drives the stop ring feeding manipulator to act, so that the stop ring feeding manipulator clamps the stop ring conveyed by the stop ring conveying mechanism from the stop ring conveying mechanism, drives the clamped stop ring to move to a ball screw pair position entering a stop ring feeding and mounting station, and mounts the clamped stop ring on the ball screw pair entering the stop ring feeding and mounting station;

and the stop ring axial installation position error-proofing mechanism is arranged on the stop ring feeding support and corrects the position of a stop ring arranged on the ball screw pair.

In a preferred embodiment of the present invention, the gap detecting device includes:

the laser range finder mounting bracket is mounted on the bottom plate;

the laser range finder mounting plate is mounted on the laser range finder mounting bracket;

the laser range finder is arranged on the laser range finder mounting plate;

a pair of guide posts mounted on the base plate;

the lifting cylinder mounting plates are fixedly mounted at the tops of the guide pillars;

the lifting cylinder is fixedly arranged on the lifting cylinder mounting plate;

a sliding plate which is arranged on the pair of guide posts in a sliding mode through a linear bearing, is connected with a piston shaft of the lifting cylinder and is driven by the lifting cylinder to move up and down along the pair of guide posts;

a detection station driving motor mounting bracket mounted on the sliding plate;

the detection station driving motor is arranged on the detection station driving motor mounting bracket;

the upper end and the lower end of the driving shaft are axially arranged on the mounting bracket of the detection station driving motor and the driving shaft on the sliding plate, the upper end of the driving shaft is connected with an output shaft of the detection station driving motor through a first coupler, and the driving shaft is driven to rotate by the detection station driving motor through the first coupler;

the encoder mounting bracket is mounted on the detection station driving motor mounting bracket;

an encoder mounted on the encoder mounting bracket;

the upper end and the lower end of the driven shaft are axially arranged on the encoder mounting bracket and the sliding plate, the driven shaft is connected with an input shaft of the encoder through a second coupling, and the driven shaft drives the encoder to work through the second coupling;

a driving pulley fixed on the driving shaft, a driven pulley fixed on the driven shaft and a transmission belt wound on the driving pulley and the driven pulley, wherein the driving shaft drives the driven shaft to rotate through the driving pulley, the transmission belt and the driven pulley;

a stop ring reset pressure plate which is arranged on the sliding plate in a sliding way through a guide post and guide sleeve mechanism, wherein the stop ring reset pressure plate is positioned below the sliding plate;

the upper end of a screw rod in the screw rod nut driving mechanism is in driving connection with the lower end of the driving shaft, and a nut in the screw rod nut driving mechanism is circumferentially fixed and axially movably mounted on the stop ring reset pressure plate;

the reset pre-tightening spring is sleeved on a screw rod in the screw rod nut driving mechanism, the upper end of the reset pre-tightening spring acts on the sliding plate, and the lower end of the reset pre-tightening spring acts on the stop ring reset pressing plate;

and the stop ring clamping manipulator is arranged on the lower end of a screw rod in the screw rod nut driving mechanism.

Owing to adopted above-mentioned technical scheme, the utility model discloses can convenient and fast find qualified mounted position, labour saving and time saving guarantees that retaining ring and installation clearance are in qualified within range, the accurate measurement clearance value simultaneously.

Drawings

Fig. 1 is the utility model discloses the automatic ball screw that parks in of car is vice retaining ring assembly and clearance detection device's schematic structure.

Fig. 2 is the schematic structural diagram of the relative position detecting device for the screw rod and the nut of the present invention.

Fig. 3 is a schematic structural view of the stop ring feeding and mounting device of the present invention.

Fig. 4 is a schematic structural diagram of the gap detecting device of the present invention.

Fig. 5 is a schematic structural view of the snap ring of the present invention.

Detailed Description

The invention is further described below with reference to the accompanying drawings and the detailed description.

Referring to fig. 1, the apparatus for assembling a ball screw pair snap ring and detecting a gap for automatic parking of an automobile shown in the drawing includes a base plate 100, and a screw nut relative position detecting station 110, a snap ring loading and mounting station 120, and a gap detecting station 130 are circumferentially disposed on the base plate 100. In addition, the bottom plate 100 further comprises a rotating motor 140, a station plate 150 is mounted on an output shaft of the rotating motor 140, a plurality of stations are circumferentially arranged on the station plate 150, a ball screw pair mounting tool 160 is mounted on each station, the station plate 150 is driven to rotate by the rotating motor 140 and drives any ball screw pair mounting tool 160 provided with the ball screw pair 200 to sequentially pass through the screw nut relative position detection station 110, the stop ring feeding and mounting station 120 and the gap detection station 130.

Referring to fig. 5, three catching positions 231 are uniformly distributed on the outer edge of the snap ring 230.

A screw nut relative position detection device 300 is installed at the screw nut relative position detection station 110 of the base plate 100, and the screw nut relative position detection device 300 detects the screw nut relative position of the ball screw pair 200, which enters the screw nut relative position detection station 110 and is assembled on any of the ball screw pair installation tools 160. The method comprises the following specific steps:

referring to fig. 2, the relative position detecting device 300 for the lead screw and the nut includes a detecting device fixing bracket 310 installed on the base plate 100, a detecting device linear guide 320 installed on the detecting device fixing bracket 310, a lead screw and nut relative position detecting mounting plate 330 installed on a slider 321 of the detecting device linear guide 320, a lead screw and nut relative position detecting mounting plate 330 installed with a lead screw spherical surface limiting tool 340, and a distance measuring resistance ruler 350 installed on a bottom surface of the lead screw and nut relative position detecting tool 340, wherein the distance measuring resistance ruler 350 extends downward. In addition, a screw and nut relative position detection driving cylinder 360 is installed on the detection device fixing bracket 310, and the screw and nut relative position detection installation plate 330 is fixedly installed on a piston rod of the screw and nut relative position detection driving cylinder 360 and is driven by the screw and nut relative position detection driving cylinder 360 to move up and down along the linear guide rail 320.

The detection method of the relative position detection device 300 for the screw rod and the nut is as follows:

after the assembly of the screw, the nut, the steel ball and the spring in the ball screw pair is completed, the assembled ball screw pairs 200 are installed on the ball screw pair installation tool 160 one by one through a mechanical arm carrying and conveying mechanism, and then the rotary motor 140 drives the station plate 150 to rotate, so that the first ball screw pair installation tool 160 provided with the assembled ball screw pairs 200 enters the screw nut relative position detection station 110; then, a relative position detection driving cylinder 360 of the screw rod and the nut is started, the relative position detection driving cylinder 360 of the screw rod and the nut drives a relative position detection mounting plate 330 of the screw rod and the nut to move downwards along a linear guide rail 320, a position of a specified circle of truncation on the spherical surface of the screw rod 210 on the ball screw pair 200 is found through a screw rod spherical surface limiting tool 340 mounted on the relative position detection mounting plate 330 of the screw rod and the nut, the position is taken as a positioning point, the relative position of the spherical surface of the screw rod 210 in the ball screw pair 200 and the end surface of the nut 220 is determined through a distance measurement resistance ruler 350, and the relative position detection of the screw rod and; after the detection of the relative position of the screw rod and the screw nut is finished, the screw rod and screw nut relative position detection driving cylinder 360 drives the screw rod and screw nut relative position detection mounting plate 330 to move upwards along the linear guide rail 320 to an initial position to wait for the next detection of the relative position of the screw rod and the screw nut; meanwhile, the rotary motor 140 drives the station board 150 to rotate, so that the ball screw pair 200 with the detected relative position of the screw nut enters the snap ring loading and mounting station 120.

A snap ring loading and mounting device 400 installed at the snap ring loading and mounting station 120 on the base plate 100, the snap ring loading and mounting device 400 axially mounts a snap ring 230 (see fig. 5) on the screw 210 of the ball screw pair 200 entering the snap ring loading and mounting station 120. The method comprises the following steps:

referring to fig. 3, the snap ring loading and mounting apparatus 400 shown therein includes a snap ring transfer mechanism 410 installed at the snap ring loading and mounting station 120 of the base plate 100, the snap ring transfer mechanism 410 being configured to transfer the snap ring 230.

In addition, a stop ring loading bracket 420 is installed at the stop ring loading and mounting station 120 of the base plate 100, a stop ring loading vertical linear guide 430 is installed at the stop ring loading bracket 420, and a loading robot vertical bracket 440 is installed at a slider 431 of the stop ring loading vertical linear guide 430.

The snap ring feeding vertical driving motor 450 and the snap ring feeding vertical screw nut mechanism 460 are further mounted on the snap ring feeding support 420, an output shaft of the snap ring feeding vertical driving motor 450 is in driving connection with a screw 461 in the snap ring feeding vertical screw nut mechanism 460, a nut 462 in the snap ring feeding vertical screw nut mechanism 460 is connected with a slider 431, the snap ring feeding vertical driving motor 450 drives a screw 461 in the snap ring feeding vertical screw nut mechanism 460 to rotate, and the rotating screw 461 drives the slider 431 and the feeding manipulator vertical support 440 to move up and down along the snap ring feeding vertical linear guide 430 through a nut 462 in the snap ring feeding vertical screw nut mechanism 460.

A feeding manipulator horizontal bracket 470 is installed on the feeding manipulator vertical bracket 440, a stop ring feeding horizontal linear guide rail 480 is installed on the feeding manipulator horizontal bracket 470, and a clamping cylinder bracket 482 is installed on a slider 481 of the stop ring feeding horizontal linear guide rail 480.

In addition, a stop ring feeding horizontal driving motor 471 and a stop ring feeding horizontal screw nut mechanism 472 are further mounted on the feeding manipulator horizontal support 470, an output shaft of the stop ring feeding horizontal driving motor 471 is in driving connection with a screw 472a in the stop ring feeding horizontal screw nut mechanism 472, a nut 472b in the stop ring feeding horizontal screw nut mechanism 472 is connected with a clamping cylinder support 482, the stop ring feeding horizontal driving motor 471 drives a screw 471 in the stop ring feeding horizontal screw nut mechanism 472 to rotate, and the rotating screw 471 drives the clamping cylinder support 482 to move back and forth along the stop ring feeding horizontal linear guide rail 480 through the nut 472b in the stop ring feeding horizontal screw nut mechanism 472.

A clamp cylinder 483 and a stop ring feeding robot 484 are installed on the clamp cylinder bracket 482, and the clamp cylinder 483 drives the stop ring feeding robot 484 to operate, so that the stop ring feeding robot 482 grips and releases the stop ring 230.

In addition, a snap ring axial installation position error prevention mechanism 490 is installed at a proper position of the snap ring loading bracket 420, and the snap ring axial installation position error prevention mechanism 490 corrects the position of the snap ring 230 installed to the ball screw pair 200.

The method of use of the snap ring loading and installation apparatus 400 is as follows:

after the ball screw pair 200 detected by the screw nut relative position detection station 110 enters the stop ring feeding and mounting station 120, the stop ring feeding vertical driving motor 450 is started, the stop ring feeding vertical driving motor 450 drives the screw 461 in the stop ring feeding vertical screw nut mechanism 460 to rotate, the rotating screw 461 drives the feeding manipulator vertical bracket 440 to move downwards along the stop ring feeding vertical linear guide rail 430 to the position of the stop ring conveying mechanism 410 through the nut 462 in the stop ring feeding vertical screw nut mechanism 460, then the stop ring feeding horizontal driving motor 471 is started to drive the screw 472a in the stop ring feeding horizontal screw nut mechanism 472 to rotate, the rotating screw 472a drives the sliding block 481 and the clamping cylinder bracket 482 to move back and forth along the stop ring feeding horizontal linear guide rail 480 through the nut 472b in the stop ring feeding horizontal screw nut mechanism 472, so that the stop ring feeding robot 484 mounted on the clamp cylinder bracket 482 is aligned with the stop ring 230 on the stop ring transfer mechanism 410, the clamp cylinder 483 is actuated to bring the stop ring feeding robot 484 to pick up the stop ring 230 from the stop ring transfer mechanism 410.

After the stop ring loading manipulator 484 grips the stop ring 230, the stop ring loading vertical driving motor 450 is started, the stop ring loading vertical driving motor 450 drives the lead screw 461 in the stop ring loading vertical lead screw nut mechanism 460 to rotate, and the rotated lead screw 461 drives the loading manipulator vertical support 440 to move upwards along the stop ring loading vertical linear guide rail 430 to the stop ring installation position through the nut 462 in the stop ring loading vertical lead screw nut mechanism 460.

Then, the stop ring feeding horizontal driving motor 471 is started to drive the lead screw 472a in the stop ring feeding horizontal lead screw nut mechanism 472 to rotate, the rotating lead screw 472a drives the sliding block 481 and the clamping cylinder bracket 482 to move forward along the stop ring feeding horizontal linear guide rail 480 to the position above the ball screw pair 200 detected by the lead screw nut relative position detection station 110 through the nut 472b in the stop ring feeding horizontal lead screw nut mechanism 472, and the directions of the stop rings 230 are the same direction in the whole stop ring 230 clamping process.

After the gripped stop ring 230 is in place, the clamp cylinder 483 is actuated, the stop ring feeding robot 484 is opened, placed on the stop ring 230 and the stop ring 230 is mounted on the screw 210 of the ball screw pair 200 detected by the screw nut relative position detecting station 110.

Since the screw 210 of the ball screw pair 200 is an external spline with 6 equal divisions and the snap ring 230 is an internal spline with 12 equal divisions, the ball screw pair 200 conveyed by the manipulator transport conveying mechanism may not be installed in place. If the snap ring 210 is not axially installed in place on the lead screw 210 of the ball screw pair 200, the snap ring axial installation position error-proofing mechanism 290 is started to perform vibration error-proofing treatment on the lead screw 210 of the ball screw pair 200, so as to ensure that the snap ring 230 is axially installed in place on the lead screw 210 of the ball screw pair 200; after the snap ring 230 is axially installed in place, the rotary motor 140 is started, and the rotary motor 140 drives the station plate 150 to rotate, so that the ball screw pair 200 with the snap ring 230 axially assembled enters the gap detection station 130.

Referring to fig. 4, a gap detecting device 500 is installed at the gap detecting station 130 of the base plate 100, and the gap detecting device 500 detects a gap between the nut 220 and the snap ring 230 of the ball screw pair 200 fitted with the snap ring 230 entering the gap detecting station 130. The method comprises the following steps:

this gap detection device 500 includes a laser range finder mounting bracket 510 mounted on the gap detection station 130 of the base plate 100, a laser range finder mounting plate 511 mounted on the laser range finder mounting bracket 510, and a laser range finder 512 mounted on the laser range finder mounting plate 511.

A pair of guide posts 520 are further mounted on the gap detection station 130 of the base plate 100, a lift cylinder mounting plate 521 is fixedly mounted on the tops of the pair of guide posts 520, and a lift cylinder 522 is fixedly mounted on the lift cylinder mounting plate 521. A slide plate 524 is slidably disposed on the pair of guide posts 520 through a linear bearing 523, and the slide plate 524 is located below the lift cylinder mounting plate 521, connected to a piston shaft of the lift cylinder 522, and driven by the lift cylinder 522 to move up and down along the pair of guide posts 520.

A detection station driving motor mounting bracket 530 is fixedly mounted on the sliding plate 524, and a detection station driving motor 531 is mounted on the detection station driving motor mounting bracket 530. The upper end and the lower end of the driving shaft 532 are respectively axially arranged on the detection station driving motor mounting bracket 530 and the sliding plate 524, the upper end of the driving shaft 532 is connected with an output shaft of the detection station driving motor 531 through a first coupler 533, and the driving shaft 532 is driven to rotate by the detection station driving motor 531 through the first coupler 533.

An encoder mounting bracket 540 is mounted on the detection station driving motor mounting bracket 530, and an encoder 541 is mounted on the encoder mounting bracket 540. The upper and lower ends of the driven shaft 542 are respectively axially provided on the encoder mounting bracket 540 and the sliding plate 524, the driven shaft 542 is connected to the input shaft of the encoder 541 via the second coupling 543, and the driven shaft 542 drives the encoder 541 to operate via the second coupling 543.

The driving shaft 532 rotates the driven shaft 542 via a belt transmission mechanism in which a driving pulley 551 is fixed to the driving shaft 532, a driven pulley 552 is fixed to the driven shaft 542, and a transmission belt 550 is wound around the driving pulley 551 and the driven pulley 552.

The stop ring return pressing plate 560 is located below the sliding plate 524 and is slidably disposed on the sliding plate 524 by a guide post and guide bush mechanism 561.

The upper end of a screw rod in the screw rod nut driving mechanism 570 is in driving connection with the lower end of the driving shaft 532, and a nut in the screw rod nut driving mechanism 570 is circumferentially fixed and axially movably arranged on the stop ring reset pressing plate 560.

A return pre-tightening spring 580 is sleeved on the lead screw in the lead screw nut driving mechanism 570, the upper end of the return pre-tightening spring 580 acts on the sliding plate 524, and the lower end of the return pre-tightening spring acts on the stop ring return pressing plate 560. A snap ring gripping robot 590 is installed at the lower end of the lead screw in the lead screw nut driving mechanism 570.

The working method of the gap detecting device 500 is as follows:

after the ball screw pair 200 with the axially mounted snap ring 230 enters the gap detection station 130, the laser range finder 512 is started to detect the gap between the snap ring 230 and the nut 220 in the ball screw pair 200, and determine whether the snap ring 230 is qualified or not and whether the mounting position of the snap ring 230 needs to be adjusted, if the snap ring is qualified, the rotating motor 140 is started, and the rotating motor 140 drives the station board 150 to rotate, so that the ball screw pair 200 with the axially mounted snap ring 230 leaves the gap detection station 140 and enters the next process.

If the position is not qualified, the lifting cylinder 522 is started, the lifting cylinder 522 drives the sliding plate 524 to move downwards along the pair of guide posts 520, the sliding plate 524 moving downwards drives the detection station driving motor 531, the first coupler 533, the driving shaft 532, the driving pulley 551, the driving belt 550, the driven pulley 552, the driven shaft 542, the encoder 541, the screw nut driving mechanism 570, the reset pre-tightening spring 580, the stop ring reset pressing plate 560 and the stop ring clamping manipulator 590 to synchronously move downwards through the detection station driving motor mounting bracket 530 and the encoder mounting bracket 540, so that the stop ring clamping manipulator 590 grabs the stop ring 230 axially mounted on the screw rod 220 of the ball screw pair 200; after the snap ring clamping manipulator 590 grabs the axially mounted snap ring 230 on the lead screw 220 of the ball screw pair 200, the lifting cylinder 500 is started again, the lifting cylinder 522 drives the sliding plate 524 to move upwards along the pair of guide posts 520, the sliding plate 524 moving upwards synchronously drives the detection station driving motor 531, the first coupler 533, the driving shaft 532, the driving pulley 551, the driving belt 550, the driven pulley 552, the driven shaft 542, the encoder 541, the lead screw nut driving mechanism 570, the reset pre-tightening spring 580, the snap ring reset pressing plate 560, the snap ring clamping manipulator 590 and the snap ring 230 grabbed by the snap ring clamping manipulator 590 to synchronously move upwards to lift the snap ring 230 to the initial position; then, a detection station driving motor 531 is started, the detection station driving motor 531 drives the stop ring clamping manipulator 590 to rotate by 30 degrees through a first coupler 533, a driving shaft 532 and a lead screw in the lead screw nut driving mechanism 570 (the gap between the stop ring 230 and the nut 220 deviates from 0.4 +/-0.2, namely, 30 degrees, so that after the stop ring 230 is installed for the first time, if the gap between the stop ring 230 and the nut 220 is unqualified, only 30 degrees need to be rotated, and an accurate position can be found), and the driving direction of the detection station driving motor 531 is determined according to the gap between the stop ring 230 and the nut 220 in the ball screw pair 200, which is detected by a laser range finder 512; the rotation angle of the detection station driving motor 531 is controlled by driving the encoder 541 synchronously with the driving shaft 532, the driving pulley 551, the driving belt 550, the driven pulley 552 and the driven shaft 542.

After the stop ring clamping manipulator 590 drives the stop ring 230 to rotate by 30 degrees, the lifting cylinder 522 is started again, the lifting cylinder 522 drives the sliding plate 524 to move downwards along the pair of guide posts 520, the sliding plate 524 moving downwards synchronously drives the detection station driving motor 531, the first coupler 533, the driving shaft 532, the driving pulley 551, the driving belt 550, the driven pulley 552, the driven shaft 542, the encoder 541, the lead screw nut driving mechanism 570, the reset pre-tightening spring 580, the stop ring reset pressing plate 560, the stop ring clamping manipulator 590 and the stop ring 230 clamped by the stop ring clamping manipulator 590 to move downwards synchronously, the snap ring 230 gripped by the snap ring gripper 590 is axially mounted on the screw 210 of the ball screw pair 200 again, and the mounted snap ring 230 drives the snap ring return pressure plate 560 to compress the same by the return pre-tightening spring 580.

After the snap ring 230 is reinstalled, the laser range finder 512 is restarted to detect the gap between the snap ring 230 and the nut 220 in the ball screw pair 200, whether the gap is qualified is judged, the detection data is uploaded to the storage system to be stored after the gap is qualified, and if the gap is not qualified, the snap ring is reinstalled again according to the steps.

Claims (4)

1. Automatic automobile parking is with vice retaining ring assembly of ball screw and clearance detection device, its characterized in that includes:

the device comprises a base plate, a screw rod and nut relative position detection station, a stop ring feeding and mounting station and a gap detection station, wherein the base plate is circumferentially provided with the screw rod and nut relative position detection station, the stop ring feeding and mounting station and the gap detection station;

a rotating electrical machine mounted on the base plate;

the working position plate is driven to rotate by the rotating motor and drives any ball screw pair mounting tool provided with the ball screw pair to sequentially pass through the screw nut relative position detection station, the stop ring feeding and mounting station and the gap detection station;

the screw rod and nut relative position detection device is arranged on the base plate and is used for detecting the relative position of a screw rod and a nut on a ball screw pair assembled on any ball screw pair installation tool and entering the screw rod and nut relative position detection station;

the stop ring feeding and mounting device is arranged on the bottom plate and is used for axially mounting a stop ring on a screw rod of a ball screw pair entering the stop ring feeding and mounting station;

and the gap detection device is arranged on the bottom plate and is used for detecting the gap between a nut and a stop ring in a ball screw pair which enters the gap detection station and is provided with the stop ring.

2. The ball screw pair snap ring assembling and gap detecting device for automatic parking of vehicles according to claim 1, wherein the screw nut relative position detecting device comprises:

a detection device fixing bracket mounted on the base plate;

the detection device linear guide rail is arranged on the detection device fixing support;

a screw rod and nut relative position detection mounting plate arranged on a slide block of the linear guide rail of the detection device;

the screw rod and nut relative position detection and driving cylinder is arranged on the detection device fixing support, the screw rod and nut relative position detection and mounting plate is fixedly arranged on a piston rod of the screw rod and nut relative position detection and driving cylinder and is driven by the screw rod and nut relative position detection and driving cylinder to move up and down along the linear guide rail;

the lead screw spherical surface limiting tool is arranged on the lead screw nut relative position detection mounting plate;

and the distance measuring resistance ruler is arranged on the bottom surface of the spherical surface limiting tool of the screw rod and extends downwards.

3. The ball screw pair snap ring assembling and gap detecting device for automatic parking of vehicles according to claim 2, wherein the snap ring loading and mounting device comprises:

a snap ring conveying mechanism mounted on the base plate, the snap ring conveying mechanism being configured to convey a snap ring;

a stop ring loading bracket mounted on the base plate;

the stop ring feeding vertical linear guide rail is arranged on the stop ring feeding support;

the feeding mechanical arm vertical support is arranged on a sliding block of the stopping ring feeding vertical linear guide rail;

a stop ring feeding vertical driving motor and a stop ring feeding vertical screw nut mechanism which are arranged on the stop ring feeding support, wherein an output shaft of the stop ring feeding vertical driving motor is in driving connection with a screw rod in the stop ring feeding vertical screw nut mechanism, a nut in the stop ring feeding vertical screw nut mechanism is connected with a slide block of a stop ring feeding vertical linear guide rail, the stop ring feeding vertical driving motor drives the screw rod in the stop ring feeding vertical screw nut mechanism to rotate, and the rotating screw rod drives the feeding manipulator vertical support to move up and down along the stop ring feeding vertical linear guide rail through the nut in the stop ring feeding vertical screw nut mechanism;

the feeding mechanical arm horizontal support is arranged on the feeding mechanical arm vertical support;

a stop ring feeding horizontal linear guide rail arranged on the horizontal bracket of the feeding manipulator;

the clamping cylinder bracket is arranged on a sliding block of the stop ring feeding horizontal linear guide rail;

the output shaft of the stop ring feeding horizontal driving motor is in driving connection with a screw rod in the stop ring feeding horizontal screw rod nut mechanism, a nut in the stop ring feeding horizontal screw rod nut mechanism is connected with the clamping cylinder support, the stop ring feeding horizontal driving motor drives the screw rod in the stop ring feeding horizontal screw rod nut mechanism to rotate, and the rotating screw rod drives the clamping cylinder support to move back and forth along the stop ring feeding horizontal linear guide rail through the nut in the stop ring feeding horizontal screw rod nut mechanism;

the clamping cylinder and the stop ring feeding manipulator are mounted on the clamping cylinder support, the clamping cylinder drives the stop ring feeding manipulator to act, so that the stop ring feeding manipulator clamps the stop ring conveyed by the stop ring conveying mechanism from the stop ring conveying mechanism, drives the clamped stop ring to move to a ball screw pair position entering a stop ring feeding and mounting station, and mounts the clamped stop ring on the ball screw pair entering the stop ring feeding and mounting station;

and the stop ring axial installation position error-proofing mechanism is arranged on the stop ring feeding support and corrects the position of a stop ring arranged on the ball screw pair.

4. The ball screw pair snap ring assembling and gap detecting device for automatic parking of vehicles according to claim 3, wherein the gap detecting device comprises:

the laser range finder mounting bracket is mounted on the bottom plate;

the laser range finder mounting plate is mounted on the laser range finder mounting bracket;

the laser range finder is arranged on the laser range finder mounting plate;

a pair of guide posts mounted on the base plate;

the lifting cylinder mounting plates are fixedly mounted at the tops of the guide pillars;

the lifting cylinder is fixedly arranged on the lifting cylinder mounting plate;

a sliding plate which is arranged on the pair of guide posts in a sliding mode through a linear bearing, is connected with a piston shaft of the lifting cylinder and is driven by the lifting cylinder to move up and down along the pair of guide posts;

a detection station driving motor mounting bracket mounted on the sliding plate;

the detection station driving motor is arranged on the detection station driving motor mounting bracket;

the upper end and the lower end of the driving shaft are axially arranged on the mounting bracket of the detection station driving motor and the driving shaft on the sliding plate, the upper end of the driving shaft is connected with an output shaft of the detection station driving motor through a first coupler, and the driving shaft is driven to rotate by the detection station driving motor through the first coupler;

the encoder mounting bracket is mounted on the detection station driving motor mounting bracket;

an encoder mounted on the encoder mounting bracket;

the upper end and the lower end of the driven shaft are axially arranged on the encoder mounting bracket and the sliding plate, the driven shaft is connected with an input shaft of the encoder through a second coupling, and the driven shaft drives the encoder to work through the second coupling;

a driving pulley fixed on the driving shaft, a driven pulley fixed on the driven shaft and a transmission belt wound on the driving pulley and the driven pulley, wherein the driving shaft drives the driven shaft to rotate through the driving pulley, the transmission belt and the driven pulley;

a stop ring reset pressure plate which is arranged on the sliding plate in a sliding way through a guide post and guide sleeve mechanism, wherein the stop ring reset pressure plate is positioned below the sliding plate;

the upper end of a screw rod in the screw rod nut driving mechanism is in driving connection with the lower end of the driving shaft, and a nut in the screw rod nut driving mechanism is circumferentially fixed and axially movably mounted on the stop ring reset pressure plate;

the reset pre-tightening spring is sleeved on a screw rod in the screw rod nut driving mechanism, the upper end of the reset pre-tightening spring acts on the sliding plate, and the lower end of the reset pre-tightening spring acts on the stop ring reset pressing plate;

and the stop ring clamping manipulator is arranged on the lower end of a screw rod in the screw rod nut driving mechanism.

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