CN220976268U - Rotating sleeve on L-shaped suspension arm rotates in place and locking mechanism - Google Patents

Abstract

The invention discloses a rotating sleeve rotating in place and a locking mechanism on an L-shaped suspension arm, which solves the problem of how to realize the rotating in place and reliable locking of a rotating part in the L-shaped suspension arm of a square frame; the bottom end of a rotating sleeve of the L-shaped suspension arm is fixedly connected with a semi-annular cornice, three cylindrical through holes are formed in the semi-annular cornice at equal intervals, a pluggable positioning pin is arranged on one cylindrical through hole in the middle, a pin hole barrel with a stepped inner through hole is fixedly connected with the other two cylindrical pin holes, the diameter of an upper stepped hole of the pin hole barrel is larger than that of a lower joint hole, positioning steel balls which are pressed downwards are arranged in the two stepped holes, the lower ends of the positioning steel balls can extend out to the lower side of the pin hole barrel, four pin holes are formed in the top end face of a horizontal dividing disc matched with the rotating sleeve, and the lower ends of the positioning steel balls can be movably embedded into the holes of the pin holes, so that the rotating sleeve can be accurately positioned by rotating 90; the occurrence that the pointed cone surface of the locking pin and the locking hole cannot be locked into the hole is avoided.

Description

Rotating sleeve on L-shaped suspension arm rotates in place and locking mechanism

Technical Field

The invention relates to a reversed loading lifting appliance on an automobile automation production line, in particular to a rotary sleeve rotary in-place and locking mechanism of an L-shaped suspension arm on a square frame lifting appliance on the automobile automation production line.

Background

On a car body coating assembly line for automatic production of automobiles, automatic gluing of the bottom of the car body is an important process after pretreatment electrophoresis; the automobile body on the assembly line is transferred to an automobile body bottom gluing station and then transferred to a square frame lifting appliance, and after automatic gluing of the automobile body bottom is carried out on the square frame lifting appliance, the automobile body on the assembly line is transferred to other process stations of the assembly line to carry out next process operation; the four rotatable L-shaped suspension arms are arranged on the square frame lifting appliance, the four L-shaped suspension arms support and hold up the bottom of an automobile body, a square frame on the upper part of the lifting appliance runs on a friction conveying roller line, the four L-shaped suspension arms on the square frame lifting appliance are rotatable suspension arms, 90-degree rotation can be realized, when the rotary arms in the four suspension arms are rotated out of the square frame, the supporting of the automobile body is realized, and when the rotary arms in the four suspension arms are retracted onto the square frame, the releasing of the automobile body is realized, so that the smooth rotation and hanging of the automobile body between a skid and the lifting appliance are realized; the four L-shaped suspension arms on the existing square frame lifting appliance are composed of a fixed part and a rotating part, wherein the fixed part comprises an upper fixed sleeve, a mandrel and a horizontal dividing disc, the upper end of the mandrel is fixedly connected to the vertical central line of the fixed sleeve, the middle and lower parts of the mandrel downwards extend out of the lower part of the fixed sleeve, the mandrel at the middle and lower parts is movably sleeved with the rotating sleeve, the bottom end of the mandrel is fixedly connected with the horizontal dividing disc, and the rotating sleeve is supported by the horizontal dividing disc to realize 90-degree rotation; the rotating part of the L-shaped suspension arm comprises a rotating sleeve and a horizontal suspension arm, the horizontal suspension arm is fixedly connected to an outer side arm of the rotating sleeve, a support pin or block for supporting the bottom of the vehicle body is arranged at the farthest end of the horizontal suspension arm, the horizontal suspension arm rotates along with the rotating sleeve, and when the horizontal suspension arm rotates out of the square frame lifting appliance, the four horizontal suspension arms support the vehicle body through the support pin or block for supporting the bottom of the vehicle body arranged at the farthest end; the lower end of the rotating sleeve is connected with a locking pin mechanism, the locking pin mechanism rotates along with the rotating sleeve, the top end face of the horizontal dividing plate is provided with a plugging matching pin hole of a locking pin, when the square frame lifting appliance receives a transferred automobile body, the rotating sleeve and a horizontal cantilever arm on the rotating sleeve rotate to a position for receiving the automobile body, the locking pin in the locking pin mechanism is required to be plugged into a pin hole on the horizontal dividing plate, so that the locking of a rotating part in an L-shaped lifting arm is realized, the four L-shaped lifting arms on the square frame lifting appliance are ensured to be reliably positioned, the rotating arm is kept in a designated direction, and the stability of the automobile body relative to the lifting appliance position in the conveying process is ensured; therefore, the rotation of the four L-shaped suspension arms on the square frame lifting appliance is in place and is reliably locked, so that the automatic hanging of the automobile body on the running water conveying line is a key whether the automatic hanging can be successful or not; because the mechanical equipment is assembled with assembly errors, the assembly errors caused by machining and assembly errors frequently occur on site, and the locking pin hole are matched with each other to generate errors, and the following results are obtained through field tests: if the deviation between the locking pin and the locking hole is more than 2 mm, the phenomenon that the locking pin is blocked and cannot enter the pin hole occurs, so that the deviation of more than 15 mm occurs on a supporting pin or a block which is arranged at the most distal end of the horizontal cantilever arm of the L-shaped suspension arm and supports the bottom of the automobile body, the automatic turning and hanging of the automobile body is failed, and even the accident that the bearing pin pierces the automobile body occurs; how to achieve the rotation in place and reliable locking of the turning part in the L-shaped boom of the box frame becomes an important problem to be solved in the field.

Disclosure of Invention

The invention provides a rotating sleeve rotating in-place and locking mechanism on an L-shaped suspension arm, which solves the technical problem of how to realize the rotating in-place and reliable locking of a rotating part in the L-shaped suspension arm of a square frame.

The invention solves the technical problems by the following technical proposal:

The general conception of the invention is that: the lower end of the rotary sleeve of the L-shaped suspension arm is fixedly connected with a semi-annular cornice, three cylindrical through holes are formed in the semi-annular cornice at equal intervals, a pluggable positioning pin is arranged on the middle cylindrical through hole, a pin hole barrel with a stepped inner through hole is fixedly connected with the other two cylindrical pin holes, the diameter of an upper stepped hole of the pin hole barrel is larger than that of a lower connecting hole, positioning steel balls which are pressed downwards are arranged in the two stepped holes, the lower ends of the positioning steel balls can protrude out of the lower part of the pin hole barrel, four pin holes are formed in the top end face of a horizontal indexing disc matched with the rotary sleeve at equal intervals in 90-degree radian, the lower ends of the positioning steel balls can be movably embedded into the holes of the pin holes, after the rotary sleeve rotates for 90 degrees, the lower ends of the positioning steel balls in the two stepped holes enter the holes, accurate positioning of the rotary sleeve rotating for 90 degrees is realized, and then the locking pin is arranged in a third pin hole, so that the rotary part in the L-shaped suspension arm can be rotated in place and locked reliably, and the automatic rotating and hanging of an automobile body is ensured.

The rotating sleeve on the L-shaped suspension arm rotates in place and a locking mechanism comprises a fixed sleeve, a rotating sleeve and a horizontal cantilever arm, wherein a mandrel extending downwards is fixedly connected to the fixed sleeve, a horizontal dividing plate is fixedly connected to the lower end of the mandrel, a first lower pin hole, a second lower pin hole, a third lower pin hole and a fourth lower pin hole are respectively arranged on the top end surface of the horizontal dividing plate in an equidistant radian manner, the rotating sleeve is movably sleeved on the mandrel below the fixed sleeve, and the horizontal cantilever arm is fixedly connected to the outer side wall of the rotating sleeve; the lower end of the rotary sleeve is fixedly connected with a semi-annular horizontal cornice, a first upper pin hole, a second upper pin hole and a third upper pin hole are respectively arranged on the semi-annular horizontal cornice at intervals, a first pin sleeve is welded in the first upper pin hole, a second pin sleeve is welded in the second upper pin hole, a third pin sleeve is welded in the third upper pin hole, the structure of the first pin sleeve is identical to that of the third pin sleeve, a through hole in the barrel of the third pin sleeve is a step through hole with a large upper part and a small lower part, an annular arc-shaped closing surface is arranged at the lower end of the step through hole, an internal thread is arranged in an upper port of the step through hole, a positioning steel ball is movably arranged in the step through hole, a spring is in compression joint on the positioning steel ball, a spring compression bolt is in compression joint with the internal thread arranged in the upper port of the step through hole, the lower hemispherical surface of the positioning steel ball is in close joint with the annular arc-shaped closing surface, and the lower spherical surface of the positioning steel ball protrudes out to the lower port of the third pin sleeve and then is movably embedded into the upper port of the fourth pin hole; a positioning bolt is movably inserted in the second pin sleeve, and the lower end of the positioning bolt is movably inserted in the third lower pin hole.

The second positioning steel ball is movably arranged in the step through hole of the first pin sleeve, a second spring is crimped on the second positioning steel ball, a second spring compression bolt is crimped on the second spring, the second spring compression bolt is screwed on an internal thread arranged in the upper port of the step through hole, and the lower end spherical surface of the second positioning steel ball is movably embedded into the upper port of the second lower pin hole after protruding out of the lower port of the first pin sleeve.

The positioning bolt is a step pin, an external thread is arranged at the upper end of the positioning bolt, an internal thread is arranged on the upper port of the second pin sleeve, a step through hole with a large upper part and a small lower part is arranged in the second pin sleeve, a pressure spring is sleeved in the middle of the positioning bolt, the lower end of the pressure spring is propped against the step of the through hole of the second pin sleeve, the upper end of the positioning bolt is in threaded connection with the upper port of the second pin sleeve, and the lower end of the positioning bolt is movably inserted into a third lower pin hole.

A vehicle body supporting block is arranged on the top surface of the far end of the horizontal cantilever arm; the L-shaped suspension arm composed of the fixed sleeve, the rotating sleeve and the horizontal suspension arm is suspended and fixed on the square frame lifting appliance; four L-shaped suspension arms for supporting the automobile body are arranged on the square lifting appliance.

The rotating sleeve on the L-shaped suspension arm rotates in place and the locking method comprises the following steps:

The first step, the rotating sleeve drives the horizontal cantilever arm to rotate anticlockwise under the drive of the rotary driving mechanism, in the process, the semi-annular horizontal cornice and the first pin sleeve, the second pin sleeve and the third pin sleeve on the semi-annular horizontal cornice rotate together with the rotating sleeve, and the lower spherical surface of the positioning steel ball and the lower spherical surface of the second positioning steel ball are movably propped against the top end surface of the horizontal dividing plate; when the rotating sleeve rotates for 90 degrees, the lower port of the third pin sleeve rotates to be right above the fourth lower pin hole, the positioning steel ball in the third pin sleeve moves downwards under the action of the spring, the lower spherical surface of the positioning steel ball is abutted with the annular arc-shaped closing-in surface arranged at the lower end of the step through hole, and the lower spherical surface of the positioning steel ball protrudes out of the lower port of the third pin sleeve and is movably embedded into the upper port of the fourth lower pin hole; meanwhile, the lower port of the first pin sleeve rotates to be right above the second lower pin hole, the second positioning steel ball in the first pin sleeve moves downwards under the action of the second spring, the lower spherical surface of the second positioning steel ball is abutted with the annular arc-shaped closing-in surface arranged at the lower end of the step through hole in the first pin sleeve, and the lower spherical surface of the second positioning steel ball protrudes out of the lower port of the first pin sleeve and is movably embedded into the upper port of the second lower pin hole; at this time, the lower port of the second pin sleeve is rotated to be directly above the third pin hole; thereby realizing the rotation of the rotary sleeve in place;

And secondly, moving the positioning bolt downwards, enabling the lower end of the positioning bolt to be inserted into the third lower pin hole, and realizing the rotary locking of the rotary sleeve, namely realizing the locking of the horizontally-suspended arm after extending.

When the horizontal cantilever arm in the L-shaped suspension arm is required to be rotated and retracted to release the automobile body supported by the L-shaped suspension arm, the positioning bolt is pulled up firstly, the lower end of the positioning bolt is separated from the third lower pin hole, then the rotating sleeve is operated to rotate clockwise, the positioning steel ball is lifted upwards under the action of rotating force, the lower end spherical surface of the positioning steel ball is separated from the upper port of the fourth lower pin hole and rotates 90 degrees clockwise along with the semi-annular horizontal cornice, at the moment, the lower port of the third pin sleeve rotates to be right above the third lower pin hole, the positioning steel ball moves downwards under the action of the spring, the lower spherical surface of the positioning steel ball is abutted with the annular arc-shaped closing-in surface arranged at the lower end of the step through hole, the lower spherical surface of the positioning steel ball extends out to the lower port of the third pin sleeve and is embedded into the upper port of the third lower pin hole, and retraction locking of the retracted rotating sleeve is realized.

According to the invention, the rotary arm auxiliary positioning steel ball mechanism is arranged between the semi-annular horizontal cornice on the rotary sleeve and the horizontal dividing disc, so that the auxiliary positioning effect is achieved, and the rotary arm is locked in place more reliably; the auxiliary positioning steel ball can help the locking pin to smoothly enter the locking hole to complete the locking task, so that the blocking of the sharp conical surface of the locking pin and the edge of the locking hole and the accidental occurrence of incapability of locking the hole are avoided.

Drawings

FIG. 1 is a schematic view of the structure of an L-shaped boom 2 of the present invention;

fig. 2 is a schematic structural view of the fixing sleeve 3 of the present invention;

Fig. 3 is a schematic view of the structure of the rotating sleeve 4 of the present invention;

fig. 4 is a schematic structural view of the semi-annular horizontal cornice 7 of the present invention;

Fig. 5 is a diagram of the mating relationship between the components on the rotating sleeve 4 of the present invention;

Fig. 6 is a diagram showing the relationship of the third pin bushing 25, the semi-annular horizontal cornice 7, and the horizontal indexing disk 8 of the present invention;

Fig. 7 is a schematic view of the structure of the stepped through hole 26 in the third pin sleeve 25 of the present invention;

Fig. 8 is a diagram of the connection between the L-shaped boom 2 and the box spreader 1 of the present invention.

Detailed Description

The invention is described in detail below with reference to the attached drawing figures:

The rotating sleeve on the L-shaped suspension arm rotates in place and a locking mechanism comprises a fixed sleeve 3, a rotating sleeve 4 and a horizontal cantilever arm 5, wherein a mandrel 15 which extends downwards is fixedly connected to the fixed sleeve 3, a horizontal dividing disc 8 is fixedly connected to the lower end of the mandrel 15, a first lower pin hole 16, a second lower pin hole 17, a third lower pin hole 18 and a fourth lower pin hole 19 are respectively arranged on the top end surface of the horizontal dividing disc 8 at equal intervals in radian, the rotating sleeve 4 is movably sleeved on the mandrel 15 below the fixed sleeve 3, and the horizontal cantilever arm 5 is fixedly connected to the outer side wall of the rotating sleeve 4; the lower end of the rotary sleeve 4 is fixedly connected with a semi-annular horizontal cornice 7, a first upper pin hole 20, a second upper pin hole 21 and a third upper pin hole 22 are respectively arranged on the semi-annular horizontal cornice 7 at intervals, a first pin sleeve 23 is welded in the first upper pin hole 20, a second pin sleeve 24 is welded in the second upper pin hole 21, a third pin sleeve 25 is welded in the third upper pin hole 22, the structure of the first pin sleeve 23 is identical to that of the third pin sleeve 25, a cylindrical through hole of the third pin sleeve 25 is a step through hole 26 with a large upper part and a small lower part, an annular arc-shaped closing surface 27 is arranged at the lower end of the step through hole 26, an inner thread 9 is arranged in the upper end of the step through hole 26, a positioning steel ball 11 is movably arranged in the step through hole 26, a spring 12 is pressed on the positioning steel ball 11, a spring pressing bolt 13 is pressed on the spring 12 in a threaded manner, the lower hemispherical surface of the positioning steel ball 11 is completely identical to that of the annular closing surface, and the annular closing surface 27 is connected with the upper end of the step through hole 26, and the lower hemispherical surface of the positioning steel ball 11 is embedded into the fourth arc-shaped pin hole 19; a positioning bolt 14 is movably inserted in the second pin sleeve 24, and the lower end of the positioning bolt 14 is movably inserted in the third lower pin hole 18.

The second positioning steel ball 28 is movably arranged in the step through hole of the first pin sleeve 23, a second spring 29 is crimped on the second positioning steel ball 28, a second spring compression bolt 30 is crimped on the second spring 29, the second spring compression bolt 30 is screwed on an internal thread arranged in the upper port of the step through hole, and the lower end spherical surface of the second positioning steel ball 28 protrudes out of the lower part of the lower port of the first pin sleeve 23 and is movably embedded into the upper port of the second lower pin hole 17; when the rotary sleeve 4 rotates under the drive of the driving mechanism, the semi-annular horizontal cornice 7 also rotates along with the rotary sleeve, so that the positioning steel ball 11 and the second positioning steel ball 28 also rotate along with the rotary sleeve, and after the rotary sleeve 4 rotates by 90 degrees, the lower end spherical surface of the positioning steel ball 11 and the lower end spherical surface of the second positioning steel ball 28 enter into the corresponding fourth lower pin hole 19 and second lower pin hole 17 respectively, so that the rotary sleeve 4 rotates by 90 degrees; the alignment of the second pin sleeve 24 with the third lower pin bore 18 is ensured creating a prerequisite for a reliable plugging of the locating pin 14.

The positioning bolt 14 is a step pin, an external thread is arranged at the upper end of the positioning bolt 14, an internal thread is arranged on the upper port of the second pin sleeve 24, a step through hole with a large upper part and a small lower part is arranged in the second pin sleeve 24, a pressure spring 31 is sleeved in the middle of the positioning bolt 14, the lower end of the pressure spring 31 is propped against the step of the through hole of the second pin sleeve 24, the upper end of the positioning bolt 14 is in threaded connection with the upper port of the second pin sleeve 24, and the lower end of the positioning bolt 14 is movably inserted into the third lower pin hole 18; the positioning bolt 14 is reliably connected with the second pin sleeve 24 through rotation after being spliced, the pressure spring 31 is used for pressing the positioning bolt 14 in the second lower pin hole 17, the position of the rotating sleeve 4 relative to the fixed sleeve 3 is locked, and the position of the automobile body in the transferring and moving process is unchanged.

A vehicle body support block 6 is provided on the distal top surface of the horizontal cantilever arm 5; the L-shaped suspension arm 2 consisting of the fixed sleeve 3, the rotating sleeve 4 and the horizontal suspension arm 5 is fixedly hung on the square frame lifting appliance 1; four L-shaped suspension arms 2 for supporting the automobile body are arranged on the square frame lifting appliance 1; the four rotating sleeves on the four L-shaped suspension arms 2 on the square frame lifting appliance 1 synchronously rotate, and the four horizontal suspension arms 5 form stable support for the automobile body through the automobile body supporting blocks 6; when the automobile body needs to be released, the automobile body is lifted through other transfer equipment, the automobile body is supported, and the four horizontal cantilever arms 5 are synchronously retracted to the frame to open the downward moving space for the release of the automobile body.

The rotating sleeve on the L-shaped suspension arm rotates to the right and locking method, rotating sleeve on the L-shaped suspension arm rotates to the right and locking mechanism is adopted, rotating sleeve rotates to the right and locking mechanism comprises a fixed sleeve 3, rotating sleeve 4 and a horizontal cantilever arm 5, a mandrel 15 which extends downwards is fixedly connected to the fixed sleeve 3, a horizontal dividing disc 8 is fixedly connected to the lower end of the mandrel 15, a first lower pin hole 16, a second lower pin hole 17, a third lower pin hole 18 and a fourth lower pin hole 19 are respectively arranged on the top end surface of the horizontal dividing disc 8 at intervals, a rotating sleeve 4 is movably sleeved on the mandrel 15 below the fixed sleeve 3, a horizontal cantilever arm 5 is fixedly connected to the outer side wall of the rotating sleeve 4, a semi-annular horizontal cornice plate 7 is fixedly connected to the lower end of the rotating sleeve 4, a first upper pin hole 20, a second upper pin hole 21 and a third upper pin hole 22 are respectively arranged on the semi-annular horizontal cantilever arm 7 at intervals, a first pin sleeve 23 is welded to the first upper pin hole 20, a first shoulder pin 21 is respectively arranged on the top end surface of the horizontal dividing disc 8 at intervals, a second shoulder 21 is connected to the third shoulder pin 24 is provided with a compression pin 26, a compression pin 26 is arranged in the third shoulder pin 25, a compression pin 25 is arranged in the third shoulder sleeve 25, a compression pin 25 is arranged in the shoulder sleeve 25, and is in the shoulder sleeve 25 is provided with a compression pin 25, and a compression pin 25 is in a compression pin 25; a positioning bolt 14 is movably inserted in the second pin sleeve 24, and the lower end of the positioning bolt 14 is movably inserted in the third lower pin hole 18; the second positioning steel ball 28 is movably arranged in the step through hole of the first pin sleeve 23, a second spring 29 is in compression joint with the second positioning steel ball 28, a second spring compression bolt 30 is in compression joint with the second spring 29, and the second spring compression bolt 30 is in screw joint with an internal thread arranged in the upper port of the step through hole; a positioning bolt 14 is movably inserted in the second pin sleeve 24; the method is characterized by comprising the following steps of:

The first step, the rotating sleeve 4 drives the horizontal cantilever arm 5 to rotate anticlockwise under the drive of the rotary driving mechanism, in the process, the semi-annular horizontal cornice 7 and the first pin sleeve 23, the second pin sleeve 24 and the third pin sleeve 25 thereon rotate together with the rotating sleeve 4, and the lower end spherical surface of the positioning steel ball 11 and the lower end spherical surface of the second positioning steel ball 28 are movably propped against the top end surface of the horizontal dividing disc 8; when the rotary sleeve 4 rotates for 90 degrees, the lower port of the third pin sleeve 25 rotates to be right above the fourth lower pin hole 19, the positioning steel ball 11 in the third pin sleeve 25 moves downwards under the action of the spring 12, the lower spherical surface of the positioning steel ball 11 is abutted with the annular arc-shaped closing-in surface 27 arranged at the lower end of the step through hole 26, and the lower spherical surface of the positioning steel ball 11 protrudes out of the lower port of the third pin sleeve 25 and is movably embedded into the upper port of the fourth lower pin hole 19; simultaneously, the lower port of the first pin sleeve 23 rotates to be right above the second lower pin hole 17, the second positioning steel ball 28 in the first pin sleeve 23 moves downwards under the action of the second spring 29, the lower spherical surface of the second positioning steel ball 28 is abutted with the annular arc-shaped closing surface arranged at the lower end of the stepped through hole in the first pin sleeve 23, and the lower spherical surface of the second positioning steel ball 28 protrudes out to the lower part of the lower port of the first pin sleeve 23 and is movably embedded into the upper port of the second lower pin hole 17; at this time, the lower port of the second pin sleeve 24 is rotated to just above the third lower pin hole 18; thereby realizing the rotation of the rotary sleeve 4 in place;

And secondly, the positioning bolt 14 is moved downwards, so that the lower end of the positioning bolt 14 is inserted into the third lower pin hole 18, and the rotation locking of the rotating sleeve 4, namely the locking of the horizontal cantilever arm 5 after the extension is realized.

When the horizontal cantilever arm 5 in the L-shaped suspension arm 2 is required to be rotated and retracted to release the automobile body supported by the horizontal cantilever arm, the positioning bolt 14 is pulled upwards, the lower end of the positioning bolt 14 is separated from the third lower pin hole 18, then the rotating sleeve 4 is operated to rotate clockwise, under the action of rotating force, the positioning steel ball 11 is lifted upwards, the lower end spherical surface of the positioning steel ball 11 is separated from the upper port of the fourth lower pin hole 19 and rotates 90 degrees clockwise along with the semi-annular horizontal cornice 7, at the moment, the lower port of the third pin sleeve 25 rotates to be right above the third lower pin hole 18, the positioning steel ball 11 moves downwards under the action of the spring 12, the lower spherical surface of the positioning steel ball 11 is abutted with the annular arc-shaped closing surface 27 arranged at the lower end of the step through hole 26, and the lower end spherical surface of the positioning steel ball 11 extends out to the lower port of the third pin sleeve 25 and is embedded into the upper port of the third lower pin hole 18, so that locking of the retracted rotating sleeve 4 is realized.

Claims (4)

1. The utility model provides a rotating sleeve on L type davit rotates and targets in place and locking mechanical system, including fixed sleeve (3), rotating sleeve (4) and horizontal cantilever arm (5), fixedly connected with dabber (15) that stretches out downwards on fixed sleeve (3), fixedly connected with horizontal graduated disk (8) at the lower extreme of dabber (15), equidistant radian is provided with first lower pinhole (16), second lower pinhole (17), third lower pinhole (18) and fourth lower pinhole (19) respectively on the terminal surface of horizontal graduated disk (8), the activity has cup jointed rotating sleeve (4) on dabber (15) of fixed sleeve (3) below, fixedly connected with horizontal cantilever arm (5) on the lateral wall of rotating sleeve (4); the semi-annular horizontal cornice is fixedly connected with the lower end of the rotary sleeve (4), a first upper pin hole (20), a second upper pin hole (21) and a third upper pin hole (22) are respectively arranged on the semi-annular horizontal cornice (7) at intervals, a first pin sleeve (23) is welded in the first upper pin hole (20), a second pin sleeve (24) is welded in the second upper pin hole (21), a third pin sleeve (25) is welded in the third upper pin hole (22), the structure of the first pin sleeve (23) is identical with the structure of the third pin sleeve (25), a cylinder inner through hole of the third pin sleeve (25) is a step through hole (26) with a large upper part and a small lower part, an annular arc-shaped closing-in surface (27) is arranged at the lower end of the step through hole (26), an inner thread (9) is arranged in the upper end opening of the step through hole (26), a positioning steel ball (11) is movably arranged in the step through hole (26), a spring (12) is crimped on the positioning steel ball (11), the spring (12) is screwed on the positioning steel ball (11), the spring (13) is screwed on the arc-shaped closing-in surface (13) and is pressed against the annular steel ball (13) through the arc-shaped closing-in surface, after the lower end spherical surface (10) of the positioning steel ball (11) protrudes out of the lower port of the third pin sleeve (25), the positioning steel ball is movably embedded into the upper port of the fourth lower pin hole (19); a positioning bolt (14) is movably inserted in the second pin sleeve (24), and the lower end of the positioning bolt (14) is movably inserted in the third lower pin hole (18).

2. The rotating sleeve rotating in place and locking mechanism on an L-shaped suspension arm according to claim 1, wherein a second positioning steel ball (28) is movably arranged in a step through hole of the first pin sleeve (23), a second spring (29) is pressed on the second positioning steel ball (28), a second spring compression bolt (30) is pressed on the second spring (29), the second spring compression bolt (30) is screwed on an internal thread arranged in an upper port of the step through hole, and after the lower end sphere of the second positioning steel ball (28) protrudes out to the lower part of the lower port of the first pin sleeve (23), the second positioning steel ball is movably embedded into an upper port of a second lower pin hole (17).

3. The rotating sleeve rotating in-place and locking mechanism on an L-shaped suspension arm according to claim 2, wherein the positioning bolt (14) is a step pin, an external thread is arranged at the upper end of the positioning bolt (14), an internal thread is arranged on the upper port of the second pin sleeve (24), a step through hole with a large upper part and a small lower part is arranged in the second pin sleeve (24), a pressure spring (31) is sleeved in the middle part of the positioning bolt (14), the lower end of the pressure spring (31) is propped against the step of the through hole of the second pin sleeve (24), the upper end of the positioning bolt (14) is in threaded connection with the upper port of the second pin sleeve (24), and the lower end of the positioning bolt (14) is movably spliced in a third lower pin hole (18).

4. A turning sleeve turning into position and locking mechanism on an L-shaped boom according to claim 1 or 2 or 3, characterized in that a body support block (6) is provided on the distal top surface of the horizontal cantilever arm (5); an L-shaped suspension arm (2) consisting of a fixed sleeve (3), a rotating sleeve (4) and a horizontal suspension arm (5) is fixedly hung on the square frame lifting appliance (1); four L-shaped suspension arms (2) for supporting the automobile body are arranged on the square frame lifting tool (1).