CN107830358B - Control device for electric adjusting bracket of accelerator - Google Patents

Abstract

The application discloses a controlling means for accelerator electric adjustment support that this application disclosed includes: the motor unit is used for driving the lifting device of the electric adjusting bracket so as to control the lifting of the electric adjusting bracket; the terminal machine is electrically connected with the motor unit and used for controlling the motor unit to operate; the transmission device is used for mechanical transmission between the motor unit and the lifting device; the mobile trolley is used for fixing the terminal and placing the motor unit and the transmission device. According to the invention, the motor unit corresponding to the worm gear lifter one by one is used for realizing electric adjustment of the worm gear lifter, and the terminal is used for controlling the operation of the gear motor, so that the synchronous lifting of four supporting points of the bracket can be realized, the problem of locking caused by overlarge lifting amplitude difference of a single supporting point is avoided, the adjustment precision is increased, and the adjustment time is greatly shortened.

Description

Control device for electric adjusting bracket of accelerator

Technical Field

Technical Field

The application relates to the field of accelerators, in particular to a control device for an electric adjusting bracket of an accelerator.

Background

In the field of accelerators, an accelerator device generally comprises several important components, which require the use of a common support platform or a single support rack to carry the various components and bring them to a predetermined position and height. These stents generally serve two purposes: firstly, the device plays a role of a supporting platform, so that the element is close to an ideal theoretical position; the other is as a fine adjustment system, which allows the collimator personnel to conveniently, quickly and accurately collimate the element to within the required tolerance. Spallation neutron sources are high intensity proton accelerator devices consisting of low energy linacs and fast cycle synchrotrons (RCS rings). The weight of the magnet in the RCS ring is close to 20 tons, the support, adjustment and positioning are realized through a special bracket, and the alignment precision of the magnet is directly influenced by the size of the bracket adjustment essence.

The existing adjusting bracket generally adopts a laminated structure, and each layer independently realizes the adjusting function of the bracket by using a linear guide rail, and carries out displacement adjustment in a linear direction along the guide rail. The three layers are usually included, the top layer is responsible for rotary motion, the middle layer is responsible for horizontal and transverse movement, the bottom layer is responsible for horizontal and longitudinal movement, and manual adjustment is adopted for adjustment of each layer of the support. For example, the magnet support of spallation neutron source often adopts a manual adjustment mode, and the position adjustment in the height direction is difficult due to the heavy weight of the magnet. In order to enable the support to be easily adjusted, most supports adopt a worm and gear lifting mechanism. Nevertheless, the maximum adjustment force required is still as high as 60n.m. Meanwhile, in order to reduce the resistance of lifting adjustment, the reduction ratio of the worm gear and the worm is large, and a manual wrench is adopted for adjustment, so that extremely long time and extremely large manpower are required to be consumed. And the magnet support is 4 point support mode, and every supporting point all needs to be adjusted, at the process of magnet support collimation, need adjust 4 supporting points repeatedly to make the magnet support reach final position. In the process of alternately adjusting 4 worm gear elevators, a spanner needs to be pulled and pulled for many times, and the adjusting shafts of the worm gear elevators are aligned, and the same lifting and falling of 4 supporting points of a bracket cannot be guaranteed only by manpower, so that the situation that the lifting of the 4 supporting points of the bracket is asynchronous and the stress of a single worm gear is not uniform and blocked is difficult to avoid.

Disclosure of Invention

The invention provides a control device for an electric adjusting bracket of an accelerator, and aims to solve the problems that the adjusting bracket of the existing accelerator is bulky in structure and inconvenient to adjust.

The application discloses a controlling means for accelerator electric adjustment support includes:

the motor unit is used for driving the lifting device of the electric adjusting bracket so as to control the lifting of the electric adjusting bracket;

the terminal machine is used for fixing and bearing the terminal machine;

the transmission device is used for mechanical transmission between the motor unit and the lifting device;

the mobile trolley is used for fixing the terminal and placing the motor unit and the transmission device.

The control device for the accelerator electric adjusting bracket is characterized in that the lifting device is a worm gear lifter, the transmission device is a connecting rod for connecting the motor unit and the worm gear lifter, and the connecting rod is driven to rotate by a motor, so that the worm gear lifter is driven to operate.

The control device for the electric accelerator adjusting bracket comprises a pair of long connecting rods and a pair of short connecting rods.

The control device for the electric accelerator adjusting bracket comprises a motor unit, a speed reducing motor and a rack for fixing the speed reducing motor, wherein a movable pulley is arranged at the bottom of the rack.

The control device for the electric accelerator adjusting bracket comprises a frame, wherein the frame comprises a mounting bottom plate, a mounting side plate, a mounting top plate and a speed reducing motor, the mounting side plate is arranged on the mounting bottom plate and is perpendicular to the mounting bottom plate, the mounting top plate is arranged above the speed reducing motor and is fixedly connected with the mounting side plate, the speed reducing motor is fixed on the mounting side plate, and the movable pulley is arranged on the lower surface of the mounting bottom plate.

The control device for the electric accelerator adjusting bracket is characterized in that a positioning device is further arranged on the frame and comprises a positioning screw rod penetrating through the mounting bottom plate, and an anti-slip soft rubber pad is arranged at the end part of the positioning screw rod, which is located below the mounting bottom plate.

The control device for the accelerator electric adjusting bracket is characterized in that a butterfly nut which is convenient to screw is arranged at the tail part of the positioning screw above the mounting bottom plate.

The control device for the electric accelerator adjusting bracket is characterized in that four worm and gear lifters are arranged at four feet at the bottom of the adjusting bracket in a rectangular shape, four motor units are arranged in one-to-one correspondence with the worm and gear lifters, two adjacent motor units are connected through a balance plate for preventing rollover, and the balance plate is detachably connected with the motor units fixedly.

The control device for the accelerator electric adjusting support is characterized in that a wire collecting box for collecting and releasing connecting wires of the motor unit is further arranged in the mobile trolley, and four wire collectors corresponding to the gear motors one by one are arranged in the wire collecting box.

The control device for the electric accelerator adjusting bracket comprises a gear motor and a speed reducer fixedly connected with the gear motor, wherein the speed reducer motor comprises five stepping motors, and the sleeve is arranged at one end of an output shaft of the speed reducer.

According to the control device for the electric accelerator adjusting bracket, the worm gear and worm lifter is controlled by the control device, so that the adjusting plate can automatically lift, and the inclination angle of the adjusting plate can be realized by controlling the worm gear and worm lifter synchronously and asynchronously; the horizontal adjusting structure arranged between the vertical moving plate and the translation plate can realize horizontal transverse movement, longitudinal movement and rotation movement of the translation plate relative to the vertical moving plate, so that the number of layers of the adjusting plate is reduced while automatic control of the adjusting plate is realized, a horizontal adjusting system is simplified, occupied space is small, and equipment is miniaturized. The motor unit corresponding to the worm gear lifter one by one realizes electric adjustment of the worm gear lifter, and the terminal machine controls the operation of the gear motor, so that synchronous lifting of four supporting points of the bracket can be controlled rapidly, the problem of blocking caused by overlarge lifting amplitude difference of a single supporting point is avoided, the adjustment precision is increased, and the adjustment time is shortened greatly.

Drawings

Fig. 1 is a schematic view of the overall structure of an electric adjusting bracket according to a first embodiment of the present invention;

FIG. 2 is an exploded view of an electrically adjustable bracket according to a first embodiment of the present invention;

FIG. 3 is a front view of a translation plate according to a first embodiment of the present invention;

FIG. 4 is a rear view of a translation plate according to a first embodiment of the present invention;

FIG. 5 is a schematic view of a horizontal and vertical adjustment mechanism according to a first embodiment of the present invention;

FIG. 6 is a cross-sectional view taken along line A-A of FIG. 5;

FIG. 7 is a schematic view of a horizontal transverse adjustment mechanism according to a first embodiment of the present invention;

FIG. 8 is a schematic view of a horizontal locking mechanism according to a first embodiment of the present invention;

FIG. 9 is a schematic diagram of a lifting adjustment system according to a first embodiment of the present invention;

FIG. 10 is a schematic view of a lifting locking device according to a first embodiment of the present invention;

FIG. 11 is a cross-sectional view taken along line A-A of FIG. 10;

FIG. 12 is a schematic diagram of a control device according to a first embodiment of the present invention;

FIG. 13 is a schematic diagram of a motor unit according to a first embodiment of the present invention;

FIG. 14 is a schematic view showing a usage state of the control device according to the first embodiment of the present invention;

FIG. 15 is a schematic view showing another usage status of the control device according to the first embodiment of the present invention;

fig. 16 is a schematic structural view of a winding box according to the first embodiment of the present invention;

FIG. 17 is a cross-sectional view taken along line A-A of FIG. 16;

FIG. 18 is a schematic circuit diagram of a terminal and an electrically adjustable bracket according to a first embodiment of the present invention;

fig. 19 is a schematic view showing the overall structure of an electric adjusting bracket according to a second embodiment of the present invention.

Reference numerals of the drawings in this embodiment:

a base 1; a through hole 10;

a vertical movement plate 2; a second fenestration 202;

a translation plate 3; a boss 30; a cavity 301; a first fenestration 302; a connection flange seat 31; a slider 32; a horizontal locking mechanism 33; horizontal locking bolt 331; an adjustment aperture 332; locking pads 333, 334; horizontal lock nuts 335, 336; lateral mounts 34, 35;

a horizontal longitudinal adjustment mechanism 4; a ball screw mount 40; a sliding bearing 401; a flap plate connecting shaft 402; a decelerator 403; a stepping motor 404; a thrust bearing 405; a ball screw 41; a ball screw 42; a connection flange 43; a knuckle bearing 421; a translation plate connecting shaft 422;

a horizontal lateral adjustment mechanism 5; a worm gear lifter 50; a body 51; a knuckle bearing 510; the connecting flanges 511 and 512 are used for telescoping the screw rod 52; a knuckle bearing 520; a speed reducing motor 53;

a worm gear lifter 6; lifting a screw 60; a lift lock 61; a ball socket connection 611; ball flange 612; lifting a locking bolt 62; a lifting fixing base 63; lifting locking shims 64, 65; lifting lock nuts 66, 67;

a control device 7; a mobile cart 70; a motor unit 71; a moving wheel 710; mounting a base plate 711; mounting a side plate 712; mounting a top plate 713; a gear motor 714; five-item stepper motor 7141; a speed reducer 7142; an adapter sleeve 715; a sleeve 716; positioning screw 717; a wing nut 718; an anti-slip soft rubber pad 719; a long link 721; a short link 722; a terminal 73; a touch screen 730; a PLC controller 731; a driver 732; a carrier plate 74; a winding box 75; and a winder 76.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings by way of specific embodiments.

The electric adjusting bracket for the accelerator provided in the embodiment, as shown in fig. 1 and 2, comprises a base 1 and an adjusting plate arranged on the base 1. The adjusting plate comprises a vertical moving plate 2 and a translation plate 3 which are stacked on the base 1 from bottom to top. A lifting adjusting system for controlling the whole lifting of the vertical moving plate 3 is arranged between the base 1 and the vertical moving plate 2, and a horizontal adjusting system for controlling the horizontal moving plate to move or rotate in the horizontal direction is also arranged between the vertical moving plate 2 and the horizontal moving plate 3. The horizontal adjusting system comprises a horizontal adjusting mechanism 5 for controlling the horizontal moving of the translation plate 3 along the horizontal direction and a longitudinal adjusting mechanism 4 for controlling the horizontal moving of the translation plate 3 along the horizontal and longitudinal directions. The longitudinal adjusting mechanisms are respectively arranged at two sides of the translation plate 3, when the longitudinal adjusting mechanisms at two sides of the translation plate 3 control the translation plate 3 to move along the same direction, the translation plate 3 moves along the horizontal and longitudinal direction, and when the longitudinal adjusting mechanisms at two sides control the translation plate 3 to move along two opposite directions, the translation plate 3 performs horizontal rotation movement within a certain angle range. The upper surface of the translation plate 3 is provided with a plurality of connecting flange seats 31 for bearing corresponding components, and the connecting flange seats 31 bear the weight of the electrical components together in multiple points and fix the components.

As shown in fig. 2 and 4, a boss 30 protruding downward is formed on the lower surface of the translation plate 3, and the boss 30 is in direct contact with the vertical movement plate 2, so that the translation plate 3 is supported on the surface of the vertical movement plate 2. The longitudinal adjusting mechanism is arranged between the translation plate 3 and the vertical moving plate 2, and is respectively arranged at two sides of the boss 30. The boss 30 is recessed from its bottom center surface to form a cavity 301 for receiving a lateral adjustment mechanism. Since the surface of the translation plate 3 needs to bear components with extremely large weight, such as an accelerator leading-out magnet with a weight of 20 tons, great friction exists between the boss 30 and the vertical moving plate 2 when the boss and the vertical moving plate are relatively moved. Since the device is in an accelerator tunnel environment with strong radiation, the conventional grease lubrication mode is easy to fail, and in order to solve the problem, in this embodiment, a slider 32 for reducing friction is fixed to a portion of the boss 30 contacting with the surface of the vertical moving plate 2. The sliding blocks 32 comprise a group of mutually overlapped sliding blocks, one sliding block is fixed on the bottom surface of the boss 30, the other sliding block is fixed on the corresponding position of the top surface of the vertical moving plate 2, and four supporting points are arranged between the boss 30 and the vertical moving plate 2 in the embodiment, and each supporting point is provided with a group of sliding blocks 32. The slider 32 is a brass base material, and graphite is inlaid on the contact surface. In this embodiment of the present application, the electric adjusting bracket is mainly used for carrying the accelerator leading-out magnet that needs to be aligned, and its adjusting range is relatively small, so that the area of the sliding block 32 is based on the moving range that can satisfy the translation plate 3, and it is ensured that in the moving process of the translation plate 3, two opposite sliding blocks 32 are always kept in contact with each other.

As shown in fig. 1, the lifting adjustment system comprises four worm gear lifters 6 arranged on the base 1, lifting screws 60 of the worm gear lifters 6 are in contact with the bottom surface of the vertical motion plate 2, and the four worm gear lifters 6 are divided into four supporting points to support the whole vertical motion plate 2. In this embodiment, the components carried by the translation plate 3 are mainly accelerator leading magnets, the translation plate 3 needs to bear the weight of the magnets, and for such bending magnets as leading magnets, in order to make the stress of each supporting point uniform, the connecting lines of the placing positions of the bracket connecting flange seat 31 form a parallelogram. The centroid of the quadrangle coincides with the center of gravity of the magnet. As shown in fig. 3 and fig. 4, the sliding blocks 32 at the bottom of the translation plate 3 correspond to the positions of the four worm and gear lifters 6 in the vertical direction, and are respectively positioned at four corners of the vertical movement plate 2, and the connecting lines of the sliding blocks and the four corners form a rectangle. By adopting the design, the gravity center of the translation plate 3 is overlapped with the geometric center of the connecting line of the sliding blocks 32, meanwhile, the gravity center of the vertical motion plate 2 is overlapped with the geometric center of the connecting line of the four worm and gear lifters 6, so that the bearing capacity of the bracket is improved, and a plurality of reinforcing ribs 33 are arranged inside the boss 30, so that the bending resistance of the translation plate is improved.

As shown in fig. 2, the longitudinal adjustment mechanism 4 includes a first telescopic portion and a first fixing portion, one end of the first telescopic portion is fixedly connected with the translation plate 3 through a spherical pair or a revolute pair, the first fixing portion is fixedly connected with the vertical plate 2 through a revolute pair, and the first fixing portion is used for driving the first telescopic portion to move along an axial direction (horizontal longitudinal direction) thereof, so as to drive the translation plate 3 to move along the horizontal longitudinal direction.

Specifically, as shown in fig. 5 and 6, the first fixing portion is a ball screw mounting seat 40 provided with a ball screw 41, and the ball screw mounting seat 40 is fixedly connected with the vertical moving plate 2 through a revolute pair; the first telescopic part is a ball screw 42 matched with the ball screw, one end of the ball screw 42 is meshed with the ball screw 41, and the other end of the ball screw is fixedly connected with the translation plate 3 through a moving pair or a rotating pair. Wherein, hang down and move board 2 and be equipped with the slide bearing 401 of its surface perpendicularly, ball screw mount pad 40 realizes the fixed connection who hangs down and move board 2 through a perpendicular board connecting axle 402 that suits with slide bearing 401, in this application other embodiments, slide bearing 401 and perpendicular move board connecting axle 402 still can be other forms revolute pairs, for example ball screw mount pad 40 through with hang down and move board 2 articulated, realize when translation board 3 moves along horizontal transverse direction, ball screw mount pad 40 can rotate in the direction that is on a parallel with the surface of hang down and move board 2. The ball screw mounting seat 40 is fixedly provided with a stepping motor 404 connected with a speed reducer 403, the speed reducer 403 is connected with the ball screw 41 through a thrust bearing 405, one end of the ball screw 42 is meshed with the end part of the ball screw 41, the other end of the ball screw is fixedly connected with the translation plate 2 through a joint bearing 421, and the joint bearing 421 is sleeved on a translation plate connecting shaft 422 penetrating through the surface of the translation plate 3, so that the fixed connection between the ball screw 42 and the translation plate 3 is realized. The knuckle bearing 421 is fixedly connected with the ball screw 42 through the connecting flange 43.

When the stepping motor 404 drives the ball screw 41 to rotate through the reducer 403 to drive the ball screw 42 to move towards the ball screw mounting seat 40, the ball screw 42 transmits a tensile force to the translation plate 3 through the knuckle bearing 421 and the translation plate connecting shaft 422, so that the translation plate 3 is pulled to move in a horizontal plane. When the ball screws 42 at both sides of the boss 30 pull or push the translation plate 3 in the same direction, the translation plate 3 moves longitudinally in the horizontal plane (the longitudinal direction is the axial direction of the ball screw 42), and when the ball screws 42 at both sides of the boss 30 apply a force to the translation plate 3 reversely, that is, the ball screw 42 at one side pulls the translation plate 3, and the ball screw 42 at the other side pushes the translation plate 3 in the opposite direction, the translation plate 3 rotates in the horizontal plane at this time.

The transverse adjusting mechanism 5 comprises a second fixing part and a second telescopic part, wherein the second fixing part and the second telescopic part are arranged between the two longitudinal adjusting structures 4, the second fixing part is fixedly connected with the vertical moving plate 2 through a spherical pair, one end of the second telescopic part is fixedly connected with the translation plate 3 through the spherical pair, the other end of the second telescopic part is driven by the second fixing part and can reciprocate horizontally and transversely, and accordingly the translation plate 3 is driven to move horizontally and transversely. When the translation plate 3 moves or rotates along the horizontal and longitudinal directions, the second fixing part and the vertical moving plate 2 relatively rotate through the spherical pair connecting the two, and the second telescopic part also relatively rotates with the translation plate 2 through the corresponding spherical pair.

Specifically, as shown in fig. 7, the second fixing portion is a body 51 of the worm gear lifter 50, and the second telescopic portion is a telescopic screw 52 of the worm gear lifter 50. The lower surface of the translation plate 3 is provided with a transverse installation seat 34, the upper surface of the translation plate 2 is provided with a transverse installation seat 35, a machine body 51 of the worm gear and worm lifter 50 is fixedly connected with the transverse installation seat 35 on the upper surface of the translation plate 2 through a joint bearing 510, and the end part of the telescopic screw rod 52 is fixedly connected with the transverse installation seat 34 on the lower surface of the translation plate 3 through another joint bearing 520. The joint bearing 510 is connected with the transverse mounting seat 35 through a connecting flange 511, the joint bearing 520 is connected with the transverse mounting seat 34 through a connecting flange 512, and in order to reduce the influence of the rotation action of the translation plate 3 on the horizontal transverse adjusting mechanism 5, when the horizontal longitudinal adjusting mechanism 4 controls the rotation of the translation plate 3, the rotation center of the horizontal longitudinal adjusting mechanism is coincident with the position of the joint bearing 520 in the vertical direction. The body 51 of the worm gear lifter 50 and the telescopic screw rod 52 are both disposed in the concave cavity 301 on the lower surface of the boss 30, and the rotating shafts of the knuckle bearing 510 and the knuckle bearing 520 extend longitudinally along the horizontal direction, so that the body 51 can freely rotate relative to the vertical moving plate 2 in the vertical direction, and a certain amount of activity can exist in other directions, and similarly, the telescopic screw rod 52 can freely rotate relative to the translational plate 3 in the vertical direction, and a certain amount of activity also exists in other directions. When the telescopic screw rod 52 stretches and contracts under the drive of the machine body 51, the translation plate 3 is pushed to move horizontally and transversely, and therefore the position of the translation plate 3 in the horizontal and transverse direction is adjusted.

The machine body 51 is also fixedly connected with a gear motor 53, and the gear motor 53 drives the worm gear lifter 50 to work, so that the translation plate 3 is controlled to move horizontally and transversely.

In this embodiment, when the translation plate 3 is adjusted by the horizontal and longitudinal adjustment mechanism 4, the distance between the connection point of the machine body 51 and the vertical movement plate 2 and the connection point of the telescopic screw rod 52 and the translation plate 3 will change slightly, in order to solve this problem, in this embodiment, the joint bearing 510 and the connection point of the vertical movement plate 2 are in clearance fit, and when the horizontal and longitudinal movement of the translation plate 3 exceeds the clearance fit range, the translation plate 3 will move slightly horizontally and laterally under the action of the horizontal and lateral adjustment mechanism, but this slight lateral movement is within the allowable error range of the electric adjustment bracket in the whole adjustment space, so that no influence is made. Similarly, when the translation plate 3 performs horizontal and horizontal adjustment, the horizontal and longitudinal adjustment mechanism can cause the translation plate 3 to generate a tiny longitudinal movement, and the tiny longitudinal movement is also within the allowable error range of the electric adjustment bracket.

As shown in fig. 1-4, for installation convenience, a first window 302 is provided at a position corresponding to the concave cavity 301 of the translation plate 3, the first window 302 is communicated with the concave cavity 301, and similarly, a second window 202 opposite to the first window 302 is provided at a position corresponding to the concave cavity 301 on the surface of the vertical plate 2. Due to the provision of the first and second windows 302, 202, an operating space is provided for the installation of the lateral adjustment mechanism, facilitating assembly and maintenance of the apparatus.

As shown in fig. 1 and 8, the edges on both sides of the translation plate 3 are respectively provided with a horizontal locking mechanism 33, the horizontal locking mechanism 33 comprises a horizontal locking bolt 331 which is connected with the translation plate 3 and the vertical plate 2 from bottom to top, the horizontal locking bolt 331 sequentially passes through the vertical plate 2 and the translation plate 3 from the bottom of the vertical plate 2, the surface of the translation plate 3 is provided with an adjusting hole 332, and the difference between the inner diameter of the adjusting hole 332 and the horizontal locking bolt 331 is larger than the maximum adjusting range of the translation plate 3. The surface of the translation plate 3 is also provided with a locking base plate 333 and a locking base plate 334 which are sleeved on the horizontal locking bolt 331 at positions corresponding to the adjusting holes 332, the locking base plate 333 is positioned on the upper surface of the translation plate 3, the locking base plate 334 is positioned on the lower surface of the translation plate 3, and the areas of the locking base plates 333 and 334 are larger than the adjusting holes 332, so that the surface of the adjusting holes 332 can be always covered in the adjusting process of the horizontal plate 3. The horizontal locking bolts 331 are respectively provided with horizontal locking nuts 335 and 336 for fixing the two locking base plates 333 and 334, the horizontal locking nuts 335 are positioned above the translation plate 3 to press the locking base plates 333 on the upper surface of the translation plate 3, and the horizontal locking nuts 336 are positioned below the translation plate 3 to press the locking base plates 334 on the lower surface of the translation plate 3. When the translation plate 3 is adjusted, the two horizontal locking nuts 335 and 336 are loosened in advance, so that the horizontal locking bolt 331 can freely move in the adjusting hole 332 when the translation plate 3 and the vertical moving plate 2 relatively move. After the translation plate 3 is adjusted, the horizontal locking nuts 334 are tightened, so that the two horizontal locking base plates 333 clamp the translation plate 3 in the middle, and the horizontal locking bolts 331 are kept from moving in the adjusting holes 332 by friction force among the three, so that the translation plate 3 and the vertical moving plate 2 are locked in position.

As shown in fig. 9, the end of the lifting screw 60 of the worm gear lifter 6 is fixedly connected with the vertical movement plate 2 through a ball joint bearing, as shown in fig. 6, a ball socket connection plate 611 is fixedly arranged at the bottom of the vertical movement plate 2, a ball flange 612 is fixed in the ball socket connection plate 611, and the other end of the ball flange 612 is fixedly connected with the lifting screw 61. By adopting the structural design, a rotation space with a certain angle exists between the lifting screw rod 61 and the vertical plate 2, so that the inclination angle of the vertical plate 2 in the horizontal aspect can be adjusted by only controlling the lifting height of one group of four worm and gear lifters 6 in the vertical direction to be different, and the longitudinal adjusting system can not only adjust the lifting of the vertical plate 2, but also control the inclination of the vertical plate 2.

As shown in fig. 10-11, a lifting locking device 61 is further arranged between the vertical moving plate 2 and the base 1, and comprises a lifting locking bolt 62, the tail of the lifting locking bolt 62 is fixedly connected with the bottom of the vertical moving plate 2 through a lifting fixing seat 63, a through hole 10 through which the lifting locking bolt 62 can pass is formed in the surface of the base 1, lifting locking gaskets 64 and 65 are respectively arranged on the upper surface and the lower surface of the base 1 corresponding to the through hole 10, and lifting locking nuts 66 and 67 matched with the lifting locking bolt 62 are correspondingly arranged on the lifting locking bolt 62. The lifting locking washer 64 is positioned on the upper surface of the base 1 and is provided with a lifting locking nut 66; the lifting locking washer 65 is located on the lower surface of the base 1, and a lifting locking nut 67 is located below the lifting locking washer. Wherein, the lifting locking gaskets 64 and 65 are spherical gaskets, the centers of the lifting locking gaskets are provided with concave spherical surfaces, and the holes for the lifting locking bolts 62 to pass through are arranged at the center positions of the spherical surfaces. Correspondingly, the lifting locking nuts 66 and 67 are spherical nuts matched with the spherical gaskets, and the lifting locking bolt 62 is in interference fit with the through hole 10, so that the lifting locking bolt 62 can have a certain inclined space in the through hole 10, and therefore, when the lifting plate 2 is controlled to lift and adjust, a certain inclined angle is allowed to be displayed between the lifting locking bolt and the horizontal plane, and the requirement of collimation is met.

In this embodiment, the horizontal and horizontal adjusting mechanism, that is, the longitudinal adjusting mechanism, may be a worm gear transmission device, a ball screw transmission device, or a hydraulic and pneumatic transmission device, and the transmission principle achieved by the horizontal and horizontal adjusting mechanism is the same, which is not described again.

The bottom of the worm gear lifter 6 is provided with a joint for being in butt joint with a driving device, and the joint is used for butt joint with a transmission device for driving the worm gear lifter 6 to work. The present embodiment also provides a control device 7 for controlling an electric adjusting bracket, as shown in fig. 12-15, the device includes a moving trolley 70 provided with a rotating wheel, four motor units 71 are fixed on a carrying board 74 of the moving trolley 70, a group of long connecting rods 721 and short connecting rods 722 are used for connecting the motor units 71 and the bottom joints of the worm gear lifters 6, two motor units 71 located at two sides of the carrying board 74 are in butt joint with the joints of the worm gear lifters 6 at a longer distance through the long connecting rods 721, and the other two motor units 71 are in butt joint with the joints of the two worm gear lifters 6 at a shorter distance through the short connecting rods 722. To facilitate connection of the long link 721 and the short link 722 to the worm gear lifter 6, the joints at the bottom of the worm gear lifter 6 may be abutted using universal couplings. The mobile trolley 70 is further provided with a terminal 73, the four motor units 71 are respectively and electrically connected with the terminal 73, the adjusting parameters required by the four motor units are input into the terminal 73, and the specific operation of each motor unit 71 is controlled through the terminal 73, so that the automatic control of a lifting adjusting system is realized, and the lifting of the vertical moving plate 2 is adjusted. The terminal 73 is also electrically connected with the stepping motor 404 of the horizontal and vertical adjusting mechanism 4 and the reducing motor 53 of the horizontal and horizontal adjusting mechanism 5, and controls the translation plate 3 to move horizontally and vertically by inputting adjusting parameters.

As shown in fig. 13, the motor unit 71 includes a frame including a mounting base plate 711, a mounting side plate 712 perpendicular to the mounting base plate 711, and a mounting top plate 713 parallel to the mounting base plate 711 and fixedly connected to the mounting side plate 712, the mounting side plate 712 being provided at one side edge of the mounting base plate 711. The mounting side plate 711 is fixed with a gear motor 714, wherein the gear motor 714 comprises five stepping motors 7141 and a speed reducer 7142 connected with the five stepping motors 7141, so that the gear motor 714 can be controlled more accurately. The output shaft of the speed reducer 7142 is provided with a transfer shaft sleeve 715 penetrating through the mounting side plate 711, and a sleeve 716 for abutting the connecting rod is connected to the transfer shaft sleeve 715. The bottom surface of the mounting base 711 is also provided with a moving pulley 710 to facilitate movement of the motor assembly 71. The tail of the mounting bottom plate 711 is also provided with a positioning device, which comprises a positioning screw 717 penetrating through the mounting bottom plate 711, the tail of the positioning screw 717 above the mounting bottom plate 711 is provided with a butterfly nut 718 convenient for manual screwing, and the end of the positioning screw 717 below the mounting bottom plate 711 is provided with an anti-skid soft rubber pad 719. Wherein, the positioning screw 717 penetrates through the mounting bottom plate 711 through a screw hole matched with the positioning screw 717, and the butterfly nut 718 is fixed at the tail part of the positioning screw 717. When the position of the motor unit 71 needs to be adjusted, the butterfly nut 718 is screwed until the anti-slip soft rubber mat 719 is separated from the surface of the carrier plate 74 of the mobile trolley 70 (or separated from other carrier surfaces), the motor unit 71 is pushed to move through the mobile pulley 710, and after the position adjustment is finished, the butterfly nut 718 is screwed, so that the anti-slip soft rubber mat 719 is in contact with the surface of the carrier plate, and movement of the motor unit 71 is prevented in the working process.

Depending on the height of the worm gear lift 6 from the ground, it is possible to selectively fix the motor assembly 71 to the carrier plate 74 (as shown in fig. 14) or to move the motor assembly 71 to the ground (as shown in fig. 15). When the single motor unit 71 works, the possibility of overturning itself is generated due to the reaction torque of the worm gear lifter 6, and in order to avoid the problem, the mounting top plates 713 of the adjacent two motor units 71 are fixedly connected through the balance plate 77, so that the reaction torque can be mutually offset, and the stability of the motor unit 71 during operation is ensured. Wherein, balance plate 77 is detachably connected with top mounting plate 713, facilitating the disassembly and storage of motor unit 71 in a non-use state.

As shown in fig. 16-17, the carrying board 74 is further provided with a winding box 75 for drawing in the motor units 71, a winder 76 corresponding to the four motor units 71 is arranged in the winding box 75, the winder 76 is used for winding power supply lines corresponding to the motor units 71, and when the motor units 71 need to be moved, the winding and the unwinding of the corresponding lines are realized through the winder 76, so that the winding of the lines is avoided.

As shown in fig. 18, the circuit principle of the terminal 73 and the motor unit 71 is that the terminal 73 is provided with a touch screen (POD) 730 connected to an internal PLC controller 731, each of the five stepper motors of the gear motor 714 is provided with a corresponding driver 732, and the Y0.0 port of the PLC controller 731 is a high-frequency pulse output port, and continuously emits a high-frequency input pulse for controlling the driver 732. The ports Y0.4 to Y0.7 are respectively connected with resistors R1, R2, R3, R4 for controlling the high-frequency pulse signals, and the PLC controller 731 sends different high-frequency pulse signals to control the working states of the relays KM1, KM2, KM3, KM4, so as to control the corresponding driver 732 to receive the high-frequency pulse, and further control the synchronous and asynchronous adjustment of the five stepping motors.

Example two

In this embodiment, as shown in fig. 19, each worm gear lifter 6 of the lifting adjustment system is fixedly provided with a gear motor 714, the gear motor 714 is electrically connected with a terminal 73, and the gear motor 714 solidified on the worm gear lifter 6 is controlled by the terminal 73 to realize synchronous or asynchronous operation of the four worm gear lifters 6, so as to adjust the lifting of the vertical plate 2.

According to the control device for the electric accelerator adjusting bracket, the automatic lifting of the adjusting plate is realized through the lifting adjusting system, and the inclination angle of the adjusting plate can be realized through controlling the synchronous and asynchronous of the worm and gear lifter of the lifting adjusting system; the horizontal adjusting structure arranged between the vertical moving plate and the translation plate can realize horizontal transverse movement, longitudinal movement and rotation movement of the translation plate relative to the vertical moving plate, so that the number of layers of the adjusting plate is reduced while automatic control of the adjusting plate is realized, a horizontal adjusting system is simplified, occupied space is small, and equipment is miniaturized. The motor unit corresponding to the worm gear lifter one by one realizes electric adjustment of the worm gear lifter, and the terminal machine controls the operation of the gear motor, so that synchronous lifting of four supporting points of the bracket can be controlled rapidly, the problem of blocking caused by overlarge lifting amplitude difference of a single supporting point is avoided, the adjustment precision is increased, and the adjustment time is shortened greatly.

The foregoing is a further detailed description of the present application in connection with the specific embodiments, and it is not intended that the practice of the present application be limited to such descriptions. It will be apparent to those skilled in the art from this disclosure that several simple deductions or substitutions can be made without departing from the inventive concepts of the present application.

Claims (10)

1. A control device for an accelerator electric adjustment bracket, characterized by comprising:

the motor unit is used for driving the lifting device of the electric adjusting bracket so as to control the lifting of the electric adjusting bracket, the lifting device is a worm gear lifter, the number of the worm gear lifters is four, the number of the motor unit is four corresponding to the number of the worm gear lifters one by one, the worm gear lifters are arranged in a rectangular shape on four feet at the bottom of the adjusting bracket, two adjacent motor units are connected through a balance plate for preventing rollover, and the motor unit comprises a gear motor;

the terminal is electrically connected with the speed reducing motor and used for controlling the operation of the speed reducing motor so as to realize synchronous or asynchronous actions of the four worm and gear lifters and realize synchronous lifting or tilting of the bracket;

the electric adjusting support comprises a vertical moving plate, the end part of a lifting screw rod of the worm gear and worm lifter is fixedly connected with the vertical moving plate of the support through a ball joint bearing, a ball socket connecting disc is fixedly arranged at the bottom of the vertical moving plate, a ball flange is fixed in the ball socket connecting disc, and the other end of the ball flange is fixedly connected with the lifting screw rod to provide a rotating space;

the transmission device is used for mechanical transmission between the motor unit and the lifting device;

and the mobile trolley is used for fixing and bearing the terminal.

2. The control device for an electric adjusting bracket of an accelerator according to claim 1, wherein the transmission means is a connecting rod connecting the motor unit and the worm gear lifter, and the connecting rod is driven to rotate by a motor so as to drive the worm gear lifter to operate.

3. The control device for an electrically adjustable bracket for an accelerator according to claim 2, wherein the link includes a pair of long links and a pair of short links.

4. The control device for an electric adjusting bracket for an accelerator according to claim 2, wherein the motor unit further comprises a frame to which a gear motor is fixed, and a moving pulley is provided at a bottom of the frame.

5. The control device for an electric adjusting bracket for an accelerator according to claim 4, wherein the frame includes a mounting base plate, a mounting side plate provided on the mounting base plate and perpendicularly to the mounting base plate, and a mounting top plate fixedly connected to the mounting side plate above the gear motor, the gear motor is fixed to the mounting side plate, and the moving sheave is located on a lower surface of the mounting base plate.

6. The control device for the electric accelerator adjusting bracket according to claim 5, wherein a positioning device is further arranged on the frame, the positioning device comprises a positioning screw rod penetrating through the mounting bottom plate, and an anti-slip soft rubber pad is arranged at the end part of the positioning screw rod, which is positioned below the mounting bottom plate.

7. The control device for an electric adjusting bracket for an accelerator according to claim 6, wherein a wing nut for facilitating screwing of the screw is provided at a tail portion of the positioning screw above the mounting base plate.

8. The control device for an electrically adjustable bracket for an accelerator of claim 5, wherein the balance plate is detachably fixedly connected to the motor unit.

9. The control device for the electric accelerator adjusting bracket according to claim 8, wherein a wire collecting box for collecting and releasing the motor unit connecting wire is further arranged in the mobile trolley, and four wire collectors which are in one-to-one correspondence with the gear motors are arranged in the wire collecting box.

10. The control device for an electric adjusting bracket of an accelerator according to claim 9, further comprising a sleeve, wherein the speed reducing motor comprises five stepping motors and a speed reducer fixedly connected with the stepping motors, and the sleeve is arranged at one end of an output shaft of the speed reducer.