CN114737743A - Dish is detained support contactless elevation quick adjustment device with monitoring system - Google Patents

Abstract

The invention belongs to the technical field of constructional engineering, and particularly relates to a disc buckle support contactless elevation quick adjusting device with a monitoring system, which aims to solve the technical problems that automatic leveling is required to be manually carried out and automatic leveling cannot be carried out; can drive the inside side motion simultaneously of drive arc cooperation suit one and arc cooperation suit two through the transmission of cooperation arc pole and rack and pinion transmission group to make arc cooperation suit one and arc cooperation suit two detain the contact with the dish simultaneously, and the drive-disc is detained along the pole setting motion, and the motion of detaining through the dish drives adjusting part and height measuring instrument subassembly and carries out height control simultaneously.

Description

Dish is detained support contactless elevation quick adjustment device with monitoring system

Technical Field

The invention belongs to the technical field of constructional engineering, and particularly relates to a disc buckle support non-contact type elevation rapid adjusting device with a monitoring system.

Background

In recent years, with the progress of urbanization, urban population has increased sharply, and buildings have been promoted to grow to higher floors due to limited land supply. In order to facilitate workers to go up and down on a construction site, a scaffold needs to be erected outside the structure. The coil buckle type scaffold has the advantages of firm connection, stable structure, convenience in construction, overall attractiveness and the like as a novel scaffold, and the utilization rate of the scaffold in China is higher and higher. All materials of the buckle type scaffold are processed in a standardized way by a factory, and only assembly operation is carried out on site;

for CN201721111665.5 a dish knot formula scaffold frame bottom height adjustment device, including base and the lead screw of rigid coupling on the base, the lead screw is divided equally into several sections along the colour that vertically is applied paint by the outer wall, and the lead screw colour of adjacent high section is different, the lead screw top spin is equipped with a screw section of thick bamboo, a screw section of thick bamboo has internal thread section and external screw thread section, the pitch of internal thread section is greater than the external screw thread section, and two coarse adjusting handles have set firmly to the outer wall bottom symmetry of a screw section of thick bamboo, a screw section of thick bamboo top spin is equipped with the fine setting nut who matches with the external screw thread section, fine setting nut's periphery symmetry has set firmly two fine setting handles, but needs the manual work to make level during this technical scheme's shortcoming.

Disclosure of Invention

The invention aims to provide a disc buckle support non-contact type elevation quick adjusting device with a monitoring system, and the device is used for solving the technical problems that automatic leveling needs to be manually carried out and cannot be carried out.

In order to achieve the purpose, the invention provides a non-contact type elevation quick adjusting device for a disc buckle support with a monitoring system, which has the following specific technical scheme:

a disc buckle support contactless elevation rapid adjusting device with a monitoring system comprises a vertical rod and a disc buckle, wherein the vertical rod is in rotating threaded fit with the disc buckle;

the adjusting assembly comprises an adjusting assembly shell, a matching arc-shaped rod, an arc-shaped matching sleeve I, an arc-shaped matching sleeve II and a rack and pinion transmission set, wherein the matching arc-shaped rod is installed at the inner end of the adjusting assembly shell, one end of the rack and pinion transmission set is installed in the matching arc-shaped rod, the other end of the rack and pinion transmission set is installed on the arc-shaped matching sleeve I and the arc-shaped matching sleeve II at the same time, the rack and pinion transmission set is connected with the adjusting assembly shell, the adjusting assembly shell is connected with the fixing frame, and the disc buckle is connected between the adjusting assembly shell and the arc-shaped matching sleeve I and the arc-shaped matching sleeve II;

the vertical rod is provided with a plurality of vertical rod sliding grooves, the fixing frame is provided with a vertical sliding boss, and the vertical sliding boss is matched with one of the vertical rod sliding grooves.

Furthermore, a plurality of vertical rod vertical sliding grooves are arranged along the central axial direction of the vertical rod in a circumferential array mode.

Further, it has drive gear group to rotate to install on the adjusting part shell, and drive gear group comprises drive gear and drive gear pivot, drive gear and drive gear pivot fixed connection, the external motor of drive gear pivot, and motor housing links to each other with the adjusting part shell is fixed, and drive gear pivot rotates with the adjusting part shell to be connected.

Further, the arc cooperation suit comprises an arc sliding frame I and a half gear ring I, wherein an arc sliding frame boss I is arranged at the inner end of the arc sliding frame I, a half gear ring I is provided with a half gear ring sliding groove I, and the arc sliding frame boss I is connected with the half gear ring sliding groove I in a sliding fit mode.

Further, the two arc-shaped matching sleeve groups comprise two arc-shaped sliding frames and two half gear rings, the inner ends of the two arc-shaped sliding frames are provided with two arc-shaped sliding frame bosses, the two half gear rings are provided with two half gear ring sliding grooves, and the two arc-shaped sliding frame bosses are connected with the two half gear ring sliding grooves in a sliding matching mode.

Furthermore, it has blind hole one to open on the terminal surface of half ring gear one, is provided with blind hole cooperation boss one on another terminal surface of half ring gear one, it has blind hole two to open on the terminal surface of half ring gear two, is provided with blind hole cooperation boss two on another terminal surface of half ring gear one, blind hole one can be connected with the cooperation of blind hole cooperation boss two, and blind hole two is connected with the cooperation of blind hole cooperation boss one.

Further, the gear rack transmission set comprises a first driving rack, a first rack connecting plate, a second driving rack, a first matching rack, a second matching rack, a first cylindrical gear rotating shaft, a second cylindrical gear and a second cylindrical gear rotating shaft, wherein one end of the first driving rack is arranged on the matching arc-shaped rod, the other end of the first driving rack is arranged on the rack connecting plate, the second driving rack is also arranged on the rack connecting plate, a first rectangular frame is arranged at the upper limit of the first driving rack, a second rectangular frame is arranged at the upper limit of the second driving rack, the first rectangular frame and the second rectangular frame are both fixed with the shell of the adjusting component, the first matching rack is meshed with the first driving rack through the first cylindrical gear, the second matching rack is meshed with the second driving rack through the second cylindrical gear, a first cylindrical gear is rotatably arranged on the first cylindrical gear rotating shaft, and a first cylindrical gear rotating shaft is fixedly arranged on the shell of the adjusting component, the cylindrical gear II is rotatably arranged on the cylindrical gear rotating shaft II, and the cylindrical gear rotating shaft II is fixedly arranged on the adjusting component shell.

Furthermore, a first power supply ring and a second power supply ring are concentrically arranged on the shell of the adjusting component, a first contact terminal is arranged on the first half gear ring, a second contact terminal is arranged on the second half gear ring, the first contact terminal can be in contact with the first power supply ring, and the second contact terminal can be in contact with the second power supply ring.

Furthermore, a plurality of clamping grooves are formed in the disc buckle along the circumferential direction of the central axis, a first micro-slider capable of being driven by an electric motor is arranged on the first half gear ring, a second micro-slider capable of being driven by the electric motor is arranged on the second half gear ring, and both the second micro-slider and the first micro-slider can be connected with the clamping grooves in a matched mode.

Further, the height monitoring assembly comprises a mobile controller, a processor, a height measuring instrument and a motor controller, wherein the mobile controller is communicated with the processor, the height measuring instrument is communicated with the processor, the processor is communicated with the motor controller, and the height measuring instrument is arranged on the fixing frame.

Further, the mobile controller is a mobile remote controller.

Further, the processor comprises a CPU module, a communication module, a data storage module and a power supply module, wherein the power supply module supplies power to the CPU module, the CPU module is communicated with the communication module, the CPU module is in one-way communication with the data storage module, the mobile controller is communicated with the communication module, and the height measuring instrument and the motor controller are communicated with the CPU module.

Further, the motor controller is connected with the motor.

The invention has the advantages that:

the automatic leveling device drives the first arc-shaped matching sleeve and the second arc-shaped matching sleeve to simultaneously move inwards by matching with the transmission of the arc-shaped rod and the gear rack transmission set, enables the first arc-shaped matching sleeve and the second arc-shaped matching sleeve to simultaneously contact with the disc buckle, drives the disc buckle to move along the vertical rod, drives the adjusting assembly and the height monitoring assembly to simultaneously adjust the height by the movement of the disc buckle, and further realizes the automatic leveling process; the motor drives the driving gear rotating shaft to move, and the driving gear is driven by the driving gear rotating shaft to move, so that the driving gear drives the half gear ring I and the half gear ring II to form a complete gear ring to move conveniently.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the position of the cut line of FIG. 1;

FIG. 3 is a cross-sectional view taken along section A-A of FIG. 2;

figure 4 is a schematic view of a pole construction of the present invention;

FIG. 5 is a schematic view of the position of the cut line of FIG. 4;

FIG. 6 is a cross-sectional view taken along section B-B of FIG. 5;

FIG. 7 is a schematic view of the adjustment assembly of the present invention;

FIG. 8 is a schematic view of the position of the cut line of FIG. 7;

FIG. 9 is a cross-sectional view taken along section C-C of FIG. 8;

FIG. 10 is a schematic view of the housing of the adjustment assembly of the present invention;

FIG. 11 is a schematic view of the position of the cut line of FIG. 10;

FIG. 12 is a cross-sectional view taken along section D-D of FIG. 11;

FIG. 13 is a first view of a portion of the adjusting assembly of the present invention;

FIG. 14 is a second schematic view of a portion of the adjusting assembly of the present invention;

FIG. 15 is a structural diagram of an arc fitting kit according to the present invention;

FIG. 16 is a schematic view of the position of the cut line of FIG. 15;

FIG. 17 is a cross-sectional view taken along section E-E of FIG. 16;

FIG. 18 is a schematic view of a second arc fitting kit according to the present invention;

FIG. 19 is a schematic view of the section line position of FIG. 18;

FIG. 20 is a cross-sectional view taken along section F-F of FIG. 19;

FIG. 21 is a schematic view of a rack and pinion drive of the present invention;

FIG. 22 is a schematic view of the fixing frame of the present invention;

FIG. 23 is a schematic view of a height monitoring assembly of the present invention;

FIG. 24 is a schematic view of the adjustment assembly installation of the present invention;

fig. 25 is a partial enlarged view Q of fig. 24;

the notation in the figure is:

a vertical rod 1; vertical chute 1-1 of the vertical rod; coiling and buckling 2; a clamping groove 2-1; an adjustment assembly 3; an adjustment assembly housing 3-1; a first power supply ring 3-1-1; a second power supply ring 3-1-2; 3-1-3 of a hinged support I; 3-1-4 parts of a hinged support II; 3-1-5 parts of a hinged support; a hinged support four 3-1-6; a fifth hinged support 3-1-7; matching with the arc-shaped rod 3-2; a first arc-shaped matching sleeve group 3-3; 3-3-1 of an arc-shaped sliding frame I; 3-3-1-1 of an arc-shaped sliding frame boss I; the half gear ring I is 3-3-2; the half gear ring sliding groove I is 3-3-2-1; a first blind hole is 3-3-2-2; the blind hole is matched with the boss I3-3-2-3; a first contact terminal 3-3-2-4; 3-3-2-5 parts of a micro slide block I; an arc-shaped matching sleeve group II 3-4; 3-4-1 of an arc-shaped sliding frame II; 3-4-1-1 of an arc sliding frame boss II; 3-4-2 parts of a half gear ring II; a semi-gear ring sliding groove II is 3-4-2-1; a second blind hole is 3-4-2-2; the blind hole is matched with the second boss 3-4-2-3; a second contact terminal 3-4-2-4; 3-4-2-5 parts of a micro slide block II; 3-5 of a gear rack transmission group; a first driving rack 3-5-1; 3-5-2 parts of a rack connecting plate; a second driving rack 3-5-3; matching the rack I3-5-4; matching with a second rack 3-5-5; 3-5-6 parts of a cylindrical gear I; 3-5-7 of a cylindrical gear rotating shaft I; 3-5-8 parts of a cylindrical gear II; 3-5-9 parts of a cylindrical gear rotating shaft II; 3-5-10 of a rectangular frame I; 3-5-11 of a rectangular frame II; 3-5-12 of a sliding column; 3-5-13 parts of a spring; a drive gear set 3-6; driving gear 3-6-1; a driving gear rotating shaft 3-6-2; a height monitoring assembly 4; a fixed mount 5; and 5-1 of a vertical sliding boss.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

As shown in fig. 1-3, a disc buckle bracket contactless elevation fast adjusting device with a monitoring system comprises an upright rod 1 and a disc buckle 2, wherein the upright rod 1 is in threaded fit with the disc buckle 2 in a rotating manner, the disc buckle bracket contactless elevation fast adjusting device further comprises an adjusting component 3, a height monitoring component 4 for performing height monitoring and a fixing frame 5, the adjusting component 3 is connected with the fixing frame 5, the disc buckle 2 is connected with the adjusting component 3, and the height monitoring component 4 is installed on the fixing frame 5;

the adjusting assembly 3 comprises an adjusting assembly shell 3-1, a matching arc-shaped rod 3-2, an arc-shaped matching sleeve set I3-3, an arc-shaped matching sleeve set II 3-4 and a rack and pinion transmission set 3-5, wherein the matching arc-shaped rod 3-2 is installed at the inner end of the adjusting assembly shell 3-1, one end of the rack and pinion transmission set 3-5 is installed on the matching arc-shaped rod 3-2, the other end of the rack and pinion transmission set 3-5 is installed on the arc-shaped matching sleeve set I3-3 and the arc-shaped matching sleeve set II 3-4 at the same time, the rack and pinion transmission set 3-5 is connected with the adjusting assembly shell 3-1, the adjusting assembly shell 3-1 is connected with a fixing frame 5, and the disc buckle 2 is connected between the adjusting assembly shell 3-1 and the arc-shaped matching sleeve set I3-3, The arc-shaped matching sleeve sets are arranged between 3 and 4; with the arrangement, the driving arc-shaped matching sleeve group I3-3 and the arc-shaped matching sleeve group II 3-4 can be driven to simultaneously move inwards through the transmission of the matching arc-shaped rod 3-2 and the gear rack transmission group 3-5, the arc-shaped matching sleeve group I3-3 and the arc-shaped matching sleeve group II 3-4 are simultaneously contacted with the disc buckle 2, the disc buckle 2 is driven to move along the vertical rod 1, the adjusting component 3 and the height monitoring component 4 are driven to simultaneously adjust the height through the movement of the disc buckle 2, and the automatic leveling process is further realized;

as shown in fig. 22, the upright 1 is provided with a plurality of upright vertical sliding grooves 1-1, the fixing frame 5 is provided with a vertical sliding boss 5-1, and the vertical sliding boss 5-1 is matched with one of the upright vertical sliding grooves 1-1.

As shown in fig. 4-6, a plurality of vertical rod vertical sliding chutes 1-1 are arranged in an axial circumferential array along the central axis of the vertical rod 1.

Wherein, as shown in fig. 7-13, a driving gear set 3-6 is rotatably mounted on the adjusting component housing 3-1, the driving gear set 3-6 is composed of a driving gear 3-6-1 and a driving gear rotating shaft 3-6-2, the driving gear 3-6-1 is fixedly connected with the driving gear rotating shaft 3-6-2, the driving gear rotating shaft 3-6-2 is externally connected with a motor, a motor shell is fixedly connected with the adjusting component housing 3-1, the driving gear rotating shaft 3-6-2 is rotatably connected with the adjusting component housing 3-1, the arrangement is that the driving gear rotating shaft 3-6-2 is driven by the motor to move, and the driving gear 3-6-1 is driven by the driving gear rotating shaft 3-6-2 to move, and then the complete gear ring formed by the first half gear ring 3-3-2 and the second half gear ring 3-4-2 is driven to move conveniently by the driving gear 3-6-1.

As shown in fig. 15-17, the arc-shaped matching set I3-3 comprises an arc-shaped sliding frame I3-3-1 and a half gear ring I3-3-2, an arc-shaped sliding frame boss I3-3-1-1 is arranged at the inner end of the arc-shaped sliding frame I3-3-1, a half gear ring sliding groove I3-3-2-1 is formed in the half gear ring I3-3-2, and the arc-shaped sliding frame boss I3-3-1-1 is connected with the half gear ring sliding groove I3-3-2-1 in a sliding matching manner.

Wherein, as shown in fig. 18-20, the arc-shaped matching set II 3-4 comprises an arc-shaped sliding frame II 3-4-1 and a half gear ring II 3-4-2, the inner end of the arc-shaped sliding frame II 3-4-1 is provided with an arc-shaped sliding frame boss II 3-4-1-1, the half gear ring II 3-4-2 is provided with a half gear ring sliding groove II 3-4-2-1, the arc-shaped sliding frame boss II 3-4-1-1 is connected with the half gear ring sliding groove II 3-4-2-1 in a sliding matching way, so that a complete circular ring can be formed by the arc-shaped sliding frame I3-3-1 and the arc-shaped sliding frame II 3-4-1, and the half gear ring I3-3-2 and the half gear ring II 3-4-2 form a complete gear ring, and the disc buckle 2 is driven to vertically move along the upright rod 1 conveniently through the first half gear ring 3-3-2 and the second half gear ring 3-4-2, so that the height of the height monitoring assembly 4 is conveniently adjusted.

Wherein, as shown in fig. 17 and 20, one end face of the first half gear ring 3-3-2 is provided with a first blind hole 3-3-2-2, the other end face of the first half gear ring 3-3-2 is provided with a first blind hole matched with the boss 3-3-2-3, one end face of the second half gear ring 3-4-2 is provided with a second blind hole 3-4-2-2, the other end face of the first half gear ring 3-3-2 is provided with a second blind hole matched with the boss 3-4-2-3, the first blind hole 3-3-2-2 can be matched and connected with the second blind hole matched with the boss 3-4-2-3, the second blind hole 3-4-2-2 can be matched and connected with the first blind hole matched with the boss 3-3-2-3, due to the arrangement, the first blind hole 3-3-2-2 can be in matched connection with the second blind hole matched boss 3-4-2-3, and the second blind hole 3-4-2-2 can be in matched connection with the first blind hole matched boss 3-3-2-3, so that the first half gear ring 3-3-2 and the second half gear ring 3-4-2 can realize the pre-positioning of the first half gear ring 3-3-2 and the second half gear ring 3-4-2 in a matched manner in the process of forming a complete gear ring.

Wherein, as shown in fig. 14 and 21, the gear rack transmission set 3-5 comprises a driving rack I3-5-1, a rack connecting plate 3-5-2, a driving rack II 3-5-3, a matching rack I3-5-4, a matching rack II 3-5-5, a cylindrical gear I3-5-6, a cylindrical gear rotating shaft I3-5-7, a cylindrical gear II 3-5-8 and a cylindrical gear rotating shaft II 3-5-9, one end of the driving rack I3-5-1 is arranged on the matching arc rod 3-2, the other end of the driving rack I3-5-1 is arranged on the rack connecting plate 3-5-2, the rack connecting plate 3-5-2 is also provided with a driving rack II 3-5-3, a first rectangular frame 3-5-10 is arranged on the first driving rack 3-5-1 in a limiting manner, a second rectangular frame 3-5-11 is arranged on the second driving rack 3-5-3 in a limiting manner, the first rectangular frame 3-5-10 and the second rectangular frame 3-5-11 are both fixed with the shell 3-1 of the adjusting assembly, a first matching rack 3-5-4 is meshed with the first driving rack 3-5-1 through a first cylindrical gear 3-5-6, a first arc-shaped sliding frame 3-3-1 is arranged on the first matching rack 3-5-4, a second matching rack 3-5-5 is meshed with a second driving rack 3-5-3 through a second cylindrical gear 3-5-8, and a second arc-shaped sliding frame 3-4-1 is arranged on the second matching rack 3-5-5, the matching rack II 3-5-5 is arranged on the cylindrical gear I3-5-6 and rotatably arranged on the cylindrical gear rotating shaft I3-5-7, the cylindrical gear rotating shaft I3-5-7 is fixedly arranged on the adjusting component shell 3-1, the cylindrical gear II 3-5-8 is rotatably arranged on the cylindrical gear rotating shaft II 3-5-9, and the cylindrical gear rotating shaft II 3-5-9 is fixedly arranged on the adjusting component shell 3-1, so that the matching arc-shaped rod 3-2 is contacted with the disc buckle 2, the matching arc-shaped rod 3-2 drives the driving rack I3-5-1 to move under the pushing of the acting force of the disc buckle 2, and the rack connecting plate 3-5-2 is further driven to move by the driving rack I3-5-1, and then the driving rack II 3-5-3 is driven to move through the rack connecting plate 3-5-2, when the driving rack I3-5-1 moves, the matching rack I3-5-4 is driven to move through the cylindrical gear I3-5-6, and then the arc-shaped sliding frame I3-3-1 is driven to move through the matching rack I3-5-4, meanwhile, when the driving rack II 3-5-3 moves, the matching rack II 3-5-5 is driven to move through the cylindrical gear II 3-5-8, and then the matching rack II 3-5-5 drives the arc-shaped sliding frame II 3-4-1 to move, so that the arc-shaped sliding frame II 3-4-1 and the arc-shaped sliding frame I3-3-1 move inwards at the same time, and then the first half gear ring 3-3-2 and the second half gear ring 3-4-2 move inwards at the same time under the drive of the second arc-shaped sliding frame 3-4-1 and the first arc-shaped sliding frame 3-3-1, so that the first half gear ring 3-3-2 and the second half gear ring 3-4-2 are attached to the disc buckle 2 at the same time, at the moment, the extension part of the disc buckle 2 is arranged between the complete gear rings formed by the shell 3-1 of the adjusting component, the first half gear ring 3-3-2 and the second half gear ring 3-4-2, when the first half gear ring 3-3-2 and the second half gear ring 3-4-2 form a complete gear ring, the second micro sliding block 3-4-2-5 and the first micro sliding block 3-3-2-5 are controlled by a remote controller, so that the second micro-slider 3-4-2-5 and the first micro-slider 3-3-2-5 are both clamped in the clamping groove 2-1, a motor externally connected with the driving gear rotating shaft 3-6-2 is started at the same time, the driving gear rotating shaft 3-6-2 is driven to rotate, the driving gear 3-6-1 is driven to rotate by the driving gear rotating shaft 3-6-2, the driving gear 3-6-1 drives the first half gear ring 3-3-2 and the second half gear ring 3-4-2 to form a complete gear ring to rotate, and the disc buckle 2 is driven to rotate on the vertical rod 1 by matching the second micro-slider 3-4-2-5 and the first micro-slider 3-3-2-5 with the clamping groove 2-1, meanwhile, the disc buckle 2 is driven to move along the axial direction of the upright rod 1 through the threaded connection between the upright rod 1 and the disc buckle 2, and the adjusting component shell 3-1 and the height monitoring component 4 are driven to move through the disc buckle 2 so as to reach the preset height and complete the adjusting process; meanwhile, when the adjusting component 3 needs to be taken down, the arc-shaped sliding frame I3-3-1 and the arc-shaped sliding frame II 3-4-1 can be separated only when the half gear ring I3-3-2 is superposed with the end face of the arc-shaped sliding frame I3-3-1 and the half gear ring II 3-4-2 is superposed with the end face of the arc-shaped sliding frame II 3-4-1, so that the adjusting component 3 is convenient to take down; when the half gear ring I3-3-2 is not overlapped with the end face of the arc-shaped sliding frame I3-3-1, the external remote controller is used for controlling the micro-miniature sliding block II 3-4-2-5 and the micro-miniature sliding block I3-3-2-5 to be separated from the clamping groove 2-1, the gear ring formed by the half gear ring I3-3-2 and the half gear ring II 3-4-2 is rotated, so that the half gear ring I3-3-2 is adjusted to be overlapped with the end face of the arc-shaped sliding frame I3-3-1, and meanwhile, when the half gear ring II 3-4-2 is overlapped with the end face of the arc-shaped sliding frame II 3-4-1, the adjusting component 3 is taken down; meanwhile, when the end faces of the half gear ring I3-3-2 and the arc-shaped sliding frame I3-3-1 are not coincident, the adjusting component 3 cannot be easily taken down under the action of external force, and the moving stability of the adjusting component 3 is further ensured.

Wherein, as shown in fig. 12, a first hinged support 3-1-3 is arranged on the adjusting component housing 3-1, a first matching rack 3-5-4 is connected with the first hinged support 3-1-3 in a sliding manner, a second hinged support 3-1-4 is arranged on the adjusting component housing 3-1, a second rectangular frame 3-5-11 is arranged on the second hinged support 3-1-4, a third hinged support 3-1-5 is arranged on the adjusting component housing 3-1, a first rectangular frame 3-5-10 is arranged on the third hinged support 3-1-5, a fourth hinged support 3-1-6 is arranged on the adjusting component housing 3-1, and a second matching rack 3-5-5 is connected with the fourth hinged support 3-1-6 in a sliding fit manner, a hinged support five 3-1-7 is installed on the adjusting assembly shell 3-1, a sliding column 3-5-12 is installed on the hinged support five 3-1-7 in a sliding mode, the sliding column 3-5-12 is installed on the rack connecting plate 3-5-2, a spring 3-5-13 is arranged between the rack connecting plate 3-5-2 and the hinged support five 3-1-7, and the spring 3-5-13 is sleeved on the sliding column 3-5-12.

Wherein, as shown in fig. 12, a first power supply ring 3-1-1 and a second power supply ring 3-1-2 are concentrically arranged on the shell 3-1 of the adjusting component, a first contact terminal 3-3-2-4 is arranged on the first half gear ring 3-3-2, a second contact terminal 3-4-2-4 is arranged on the second half gear ring 3-4-2, the first contact terminal 3-3-2-4 can be contacted with the first power supply ring 3-1-1, and the second contact terminal 3-4-2-4 can be contacted with the second power supply ring 3-1-2, so that the first power supply ring 3-1-1 and the second power supply ring 3-1-2 are externally connected with the positive and negative poles of the power supply equipment, and further can be contacted with the first power supply ring 3-1-1 through the first contact terminal 3-3-2-4, the contact terminal II 3-4-2-4 can be in contact with the power supply ring II 3-1-2 to realize the power supply of the electric-driven micro slide block I3-3-2-5 arranged on the half gear ring I3-3-2 and the electric-driven micro slide block II 3-4-2-5 arranged on the half gear ring II 3-4-2, and the telescopic motion of the micro slide block II 3-4-2-5 and the micro slide block I3-3-2-5 can be controlled by a remote controller.

As shown in fig. 17 and 20, a plurality of clamping grooves 2-1 are circumferentially arrayed on the disk buckle 2 along the central axis, a first micro-slider 3-3-2-5 capable of being electrically driven is arranged on the first half-gear ring 3-3-2, a second micro-slider 3-4-2-5 capable of being electrically driven is arranged on the second half-gear ring 3-4-2, and both the second micro-slider 3-4-2-5 and the first micro-slider 3-3-2-5 can be connected with the clamping grooves 2-1 in a matching manner.

As shown in fig. 23, the height monitoring assembly 4 includes a mobile controller, a processor, a height measuring instrument and a motor controller, the mobile controller and the processor are in communication, the height measuring instrument and the processor are in communication, and the processor is in one-way communication with the motor controller.

As shown in fig. 23, the mobile controller is a mobile remote controller.

As shown in fig. 23, the processor includes a CPU module, a communication module, a data storage module, and a power supply module, the power supply module supplies power to the CPU module, the CPU module communicates with the communication module, the CPU module communicates with the data storage module in a single direction, the mobile controller communicates with the communication module, the height measuring instrument and the motor controller communicate with each other, and the height measuring instrument is mounted on the fixing frame 5.

Wherein the motor controller is connected to the motor as shown in fig. 23.

Working principle;

when the device is used, the height to be adjusted is set through the mobile remote controller, one of the disc buckle support non-contact elevation quick adjusting devices with the monitoring system is driven to reach a preset height, the disc buckle support non-contact elevation quick adjusting device with the monitoring system serves as a main body, the other disc buckle support non-contact elevation quick adjusting devices with the monitoring system are driven bodies, the height of the current driven body is obtained through measurement of a height measuring instrument in the driven body, the height difference value between the main body and the driven body is obtained through calculation of a CPU (Central processing Unit) module, the result obtained through calculation of the CPU module is converted into the number of turns of the motor in rotation, the motor controller is controlled through the communication module, the motor is controlled through the motor controller to move, the driven body is driven to move, and the driven body and the main body move through the vertical rods 1, Dish is detained 2, adjusting part 3, is used for carrying out height monitoring's height monitoring subassembly 4 and mount 5 cooperation and realizes, when reaching same height between main part and the driven body, and then realizes the automatic leveling of device.

It is to be understood that the present invention has been described with reference to certain embodiments and that various changes in form and details may be made therein by those skilled in the art without departing from the spirit and scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (10)

1. The utility model provides a set detains quick adjusting device of support contactless elevation with monitoring system, detains (2) including pole setting (1) and dish, pole setting (1) detains (2) with the dish and rotates screw-thread fit and be connected, its characterized in that, still include adjusting part (3), be used for carrying on height monitoring's height monitoring subassembly (4) and mount (5), adjusting part (3) are connected with mount (5), and dish detains (2) and is connected with adjusting part (3), and height monitoring subassembly (4) are installed on mount (5); the adjusting assembly (3) comprises an adjusting assembly shell (3-1), a matching arc-shaped rod (3-2), an arc-shaped matching sleeve set I (3-3), an arc-shaped matching sleeve set II (3-4) and a gear and rack transmission set (3-5), the matching arc-shaped rod (3-2) is installed at the inner end of the adjusting assembly shell (3-1), one end of the gear and rack transmission set (3-5) is installed on the matching arc-shaped rod (3-2), the other end of the gear and rack transmission set (3-5) is installed on the arc-shaped matching sleeve set I (3-3) and the arc-shaped matching sleeve set II (3-4) at the same time, the gear and rack transmission set (3-5) is connected with the adjusting assembly shell (3-1), the adjusting assembly shell (3-1) is connected with the fixing frame (5), the disc buckle (2) is connected between the adjusting component shell (3-1) and the arc-shaped matching sleeve group I (3-3) and the arc-shaped matching sleeve group II (3-4); a plurality of vertical rod vertical sliding grooves (1-1) are formed in the vertical rod (1), a vertical sliding boss (5-1) is installed on the fixing frame (5), and the vertical sliding boss (5-1) is matched with one of the vertical rod vertical sliding grooves (1-1).

2. The device for the contactless rapid elevation adjustment of the disc buckle support with the monitoring system according to claim 1, wherein a plurality of vertical sliding grooves (1-1) of the vertical rod are arranged in a circumferential array along the central axis of the vertical rod (1).

3. The device for quickly adjusting the elevation of the disc buckle bracket in a non-contact manner with the monitoring system according to claim 1, wherein a driving gear set (3-6) is rotatably mounted on the adjusting component housing (3-1), the driving gear set (3-6) comprises a driving gear (3-6-1) and a driving gear rotating shaft (3-6-2), the driving gear (3-6-1) is fixedly connected with the driving gear rotating shaft (3-6-2), the driving gear rotating shaft (3-6-2) is externally connected with a motor, a motor shell is fixedly connected with the adjusting component housing (3-1), and the driving gear rotating shaft (3-6-2) is rotatably connected with the adjusting component housing (3-1).

4. The disc buckle bracket non-contact type elevation quick adjustment device with the monitoring system is characterized in that the arc-shaped matching set I (3-3) comprises an arc-shaped sliding frame I (3-3-1) and a half gear ring I (3-3-2), an arc-shaped sliding frame boss I (3-3-1-1) is arranged at the inner end of the arc-shaped sliding frame I (3-3-1), a half gear ring sliding groove I (3-3-2-1) is formed in the half gear ring I (3-3-2-1), and the arc-shaped sliding frame boss I (3-3-1-1) is connected with the half gear ring sliding groove I (3-3-2-1) in a sliding matching mode.

5. The disc buckle bracket non-contact type elevation quick adjustment device with the monitoring system according to claim 1, wherein the arc-shaped matching set II (3-4) comprises an arc-shaped sliding frame II (3-4-1) and a half gear ring II (3-4-2), an arc-shaped sliding frame boss II (3-4-1-1) is arranged at the inner end of the arc-shaped sliding frame II (3-4-1), a half gear ring sliding groove II (3-4-2-1) is formed in the half gear ring II (3-4-2), and the arc-shaped sliding frame boss II (3-4-1-1) is connected with the half gear ring sliding groove II (3-4-2-1) in a sliding matching manner.

6. The disc buckle support non-contact type elevation quick adjustment device with the monitoring system according to claim 4 or 5, characterized in that one end face of the first half gear ring (3-3-2) is provided with a first blind hole (3-3-2-2), the other end face of the first half gear ring (3-3-2) is provided with a first blind hole matching boss (3-3-2-3), one end face of the second half gear ring (3-4-2) is provided with a second blind hole (3-4-2-2), the other end face of the first half gear ring (3-3-2) is provided with a second blind hole matching boss (3-4-2-3), the first blind hole (3-3-2-2) can be matched and connected with the second blind hole matching boss (3-4-2-3), the second blind hole (3-4-2-2) is connected with the first blind hole matching boss (3-3-2-3) in a matching mode.

7. The non-contact elevation quick adjustment device with the monitoring system for the disc buckle support according to claim 1, wherein the gear rack transmission set (3-5) comprises a first driving rack (3-5-1), a rack connecting plate (3-5-2), a second driving rack (3-5-3), a first matching rack (3-5-4), a second matching rack (3-5-5), a first cylindrical gear (3-5-6), a first cylindrical gear rotating shaft (3-5-7), a second cylindrical gear (3-5-8) and a second cylindrical gear rotating shaft (3-5-9), one end of the first driving rack (3-5-1) is installed on the matching arc-shaped rod (3-2), the other end of the driving rack I (3-5-1) is arranged on a rack connecting plate (3-5-2), a driving rack II (3-5-3) is further arranged on the rack connecting plate (3-5-2), a rectangular frame I (3-5-10) is arranged at the upper limit of the driving rack I (3-5-1), a rectangular frame II (3-5-11) is arranged at the upper limit of the driving rack II (3-5-3), the rectangular frame I (3-5-10) and the rectangular frame II (3-5-11) are both fixed with an adjusting component shell (3-1), and the matching rack I (3-5-4) is meshed with the driving rack I (3-5-1) through a cylindrical gear I (3-5-6), the matching rack II (3-5-5) is meshed with the driving rack II (3-5-3) through the cylindrical gear II (3-5-8), the cylindrical gear I (3-5-6) is rotatably installed on the cylindrical gear rotating shaft I (3-5-7), the cylindrical gear rotating shaft I (3-5-7) is fixedly installed on the adjusting component shell (3-1), the cylindrical gear II (3-5-8) is rotatably installed on the cylindrical gear rotating shaft II (3-5-9), and the cylindrical gear rotating shaft II (3-5-9) is fixedly installed on the adjusting component shell (3-1).

8. The device for quickly adjusting the elevation of a disc buckle bracket in a non-contact manner with a monitoring system according to claim 4 or 5, the adjusting assembly is characterized in that a first power supply ring (3-1-1) and a second power supply ring (3-1-2) are concentrically arranged on an adjusting assembly shell (3-1), a first contact terminal (3-3-2-4) is arranged on a first half gear ring (3-3-2), a second contact terminal (3-4-2-4) is arranged on a second half gear ring (3-4-2), the first contact terminal (3-3-2-4) can be in contact with the first power supply ring (3-1-1), and the second contact terminal (3-4-2-4) can be in contact with the second power supply ring (3-1-2).

9. The disc buckle bracket non-contact type elevation rapid adjusting device with the monitoring system according to claim 4 or 5, wherein a plurality of clamping grooves (2-1) are circumferentially arrayed along a central axis on the disc buckle (2), a first micro slide block (3-3-2-5) capable of being electrically driven is arranged on the first half gear ring (3-3-2), a second micro slide block (3-4-2-5) capable of being electrically driven is arranged on the second half gear ring (3-4-2), and both the second micro slide block (3-4-2-5) and the first micro slide block (3-3-2-5) can be connected with the clamping grooves (2-1) in a matching manner.

10. The device for non-contact elevation quick adjustment of the disc buckle support with the monitoring system according to claim 1 or 3, wherein the height monitoring assembly (4) comprises a mobile controller, a processor, a height measuring instrument and a motor controller, the mobile controller is in communication with the processor, the height measuring instrument is in communication with the processor, the processor is in communication with the motor controller, the height measuring instrument is mounted on the fixing frame (5), and the motor controller is connected to the motor.

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