CN220480788U - Automatic upright post assembling mechanism - Google Patents

Abstract

The utility model discloses an automatic upright post assembling mechanism, which relates to the technical field of lifting tables and comprises a fixing frame, a sliding block clamping jaw assembly, an inner pipe clamping jaw assembly and a lifting mechanism, wherein the sliding frame is vertically connected to the fixing frame in a sliding mode, the sliding block clamping jaw assembly is arranged on the fixing frame, the middle pipe clamping jaw assembly is arranged on the sliding frame, the sliding block clamping jaw assembly is arranged between the middle pipe clamping jaw assembly and the inner pipe clamping jaw assembly, and the lifting mechanism is used for driving the sliding frame to lift so that the middle pipe clamping jaw assembly can be close to or far from the sliding block clamping jaw assembly. The scheme can realize automatic assembly of the stand column.

Description

Automatic upright post assembling mechanism

Technical Field

The utility model relates to the technical field of lifting tables, in particular to an automatic upright post assembling mechanism.

Background

The lifting table is widely applied to the fields of offices, medical treatment and the like, and the common lifting table comprises a lifting upright post, wherein the lifting upright post comprises an inner pipe, a middle pipe sleeved outside the inner pipe and a sliding block used for compensating a gap between the inner pipe and the middle pipe, and the inner pipe and the middle pipe can slide relatively. In the prior art, all parts of the lifting upright post are assembled into a whole in a manual mode, so that the assembly efficiency is low, labor is consumed, the assembly cost is high, and the assembly precision of the assembled upright post is inconsistent.

Disclosure of Invention

The utility model provides an automatic upright post assembling mechanism which can realize automatic assembly of upright posts in order to overcome the defect that the lifting upright posts of a lifting table are assembled manually in the prior art.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the utility model provides an automatic equipment mechanism of stand, includes mount, vertical sliding connection in the carriage of mount, install in slider clamping jaw subassembly, inner tube clamping jaw subassembly and elevating system of mount, and install in the well pipe clamp jaw subassembly of carriage, slider clamping jaw subassembly sets up well pipe clamp jaw subassembly with between the inner tube clamping jaw subassembly, elevating system is used for driving the carriage and goes up and down, so that well pipe clamp jaw subassembly can be close to or keep away from slider clamping jaw subassembly.

According to the technical scheme, the inner pipe clamping jaw assembly clamps the inner pipe and enables the inner pipe to be fixed, the sliding block clamping jaw assembly can fix the sliding block on the outer side wall of the inner pipe, the middle pipe clamping jaw assembly clamps the middle pipe, the lifting mechanism drives the sliding frame to move up and down, one end of the middle pipe is driven to be sleeved on the outer side of the inner pipe, and the sliding block is connected to the middle pipe. In the process that the middle pipe is sleeved on the inner pipe, the sliding block clamping jaw assembly loosens the sliding block, and interference between the sliding block clamping jaw assembly and the middle pipe is avoided. According to the technical scheme, the automatic assembly of the stand column can be realized, the assembly mechanism can be started only by feeding the middle pipe, the inner pipe and the sliding block into positions through the feeding mechanism, all the parts are clamped and then assembled into a whole, and compared with manual assembly, the efficiency is higher, the assembly cost is lower, and the consistency of assembled products is higher.

Preferably, the clamping center of the sliding block clamping jaw assembly, the clamping center of the middle pipe clamping jaw assembly and the clamping center of the inner pipe clamping jaw assembly are positioned in the same vertical plane.

According to the scheme, the clamping centers of all the parts of the upright post can be aligned, assembly is convenient, and accuracy of the assembled parts is improved.

Preferably, the fixing frame is provided with a centering clamping jaw assembly, the centering clamping jaw assembly comprises a centering clamping jaw and a roller wheel rotatably arranged on the centering clamping jaw, and the clamping center of the centering clamping jaw assembly and the clamping center of the sliding block clamping jaw assembly are positioned in the same vertical plane.

According to the technical scheme, the centering clamping jaw assembly clamps the middle pipe and can be matched with the middle pipe clamping jaw assembly, so that the center position of the middle pipe is kept stable and unchanged all the time in the moving process, and the roller wheels enable the middle pipe to move up and down relative to the centering clamping jaw assembly.

Preferably, the sliding block clamping jaw assembly comprises a transverse moving frame, a first linear driver and a supporting block, wherein the transverse moving frame is transversely connected with the fixed frame in a sliding mode, the first linear driver is used for driving the transverse moving frame to slide, the supporting block is fixed on the transverse moving frame, and the supporting block is used for supporting the lower end face of the sliding block.

According to the technical scheme, when the first linear driver drives the supporting block to move and the supporting block is supported on the lower end face of the movable sliding block, the movable sliding block can be kept motionless in the middle pipe downward moving process, and the upper end of the movable sliding block can extend into the middle pipe and be clamped with the middle pipe. The first linear driver can also drive the supporting block to move and separate the supporting block from the movable slide block, so that feeding and discharging are facilitated.

Preferably, the sliding block clamping jaw assembly further comprises a compressing block transversely connected to the transverse moving frame in a sliding mode and a second linear driver used for driving the compressing block to slide, the sliding direction of the compressing block is perpendicular to that of the transverse moving frame, and a compressing part protruding out of the compressing block and used for compressing the elastic buckle on the sliding block is arranged at the lower portion of the compressing block.

In the technical scheme, the pressing part can press the elastic buckle on the movable sliding block in an internal pressure mode, and the movable sliding block can conveniently extend into the middle pipe.

Preferably, the pressing part has a U-shaped structure.

Preferably, when the compressing part compresses the elastic buckle, the height of the upper end surface of the compressing part is lower than that of the elastic buckle.

In the above technical scheme, when the compressing part compresses tightly the bullet is detained, the up end height of compressing part is less than the up end height that the bullet was detained, in the assembly process, well pipe can partly overlap earlier in the bullet detains the upper end, and well pipe has been pressed from both sides this moment the bullet is detained, guarantees the bullet is detained can not outwards pop out, and well pipe also can not with at this moment the clamping piece interferes, then unclamping the compressing part makes well pipe continue to move down, makes the bullet detain whole stretch into well pipe and with well pipe joint.

Preferably, the clamping piece and the third linear driver for driving movement are arranged on the pressing block, and the clamping piece is arranged above the pressing part and used for pressing the static sliding block.

In the technical scheme, the clamping piece can compress the static slide block, so that the static slide block is prevented from falling from the inner pipe in the assembly process.

Preferably, when the clamping piece clamps the static slide block, the height of the upper end face of the clamping piece is lower than that of the upper end face of the static slide block.

According to the technical scheme, when the clamping piece clamps the static slide block, the height of the upper end face of the clamping piece is lower than that of the upper end face of the static slide block, in the assembling process, the middle pipe can be partially sleeved at the upper end of the static slide block, the middle pipe can clamp the static slide block at the moment, the static slide block is prevented from being separated from the inner pipe, the middle pipe cannot interfere with the clamping piece at the moment, and then the clamping piece is loosened, so that the middle pipe continuously moves downwards, and the whole static slide block stretches into the middle pipe.

Preferably, the lateral moving frame is provided with an avoidance hole, and the avoidance hole is positioned below the movable sliding block when the support block is supported on the lower end surface of the movable sliding block.

Because there is certain shake in the material loading in-process, move the slider and probably follow the outer wall of inner tube downwardly the certain distance of landing, if at this moment direct clamp support piece, can make the support piece press from both sides garrulous slider. According to the technical scheme, the avoidance hole can avoid a supporting piece, the supporting piece is arranged on the mechanical arm, after loading is completed, the movable sliding block is jacked up from bottom to top through the supporting piece, the movable sliding block is moved in place, then the supporting block is clamped, and after the supporting block is moved in place, the supporting piece is withdrawn.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of a slider jaw assembly according to the present utility model;

FIG. 3 is a schematic diagram of a second embodiment of a slider jaw assembly according to the present utility model;

FIG. 4 is a partial enlarged view at B in FIG. 1;

FIG. 5 is an enlarged view of a portion of FIG. 1 at C;

FIG. 6 is a schematic view of the structure of the center pillar of the present utility model;

fig. 7 is a partial enlarged view at a in fig. 6.

In the figure: the clamping device comprises a fixing frame 1, a sliding frame 2, a sliding block clamping jaw assembly 3, a transverse moving frame 3.1, a first linear driver 3.2, a supporting block 3.3, a pressing block 3.4, a second linear driver 3.5, a clamping piece 3.6, a third linear driver 3.8, a avoiding hole 3.9, a positioning block 3.10, a pressing part 3.11, a middle pipe clamping jaw assembly 4, a middle pipe clamping jaw 4.1, a clamping groove 4.2, a limiting block 4.3, an inner pipe clamping jaw assembly 5, a lifting mechanism 6, a driving motor 6.1, a screw and nut mechanism 6.2, a guide rail sliding block 7, a centering clamping jaw assembly 8, a roller 8.1, a clamping jaw cylinder 8.2, a stand 200, a middle pipe 201, an inner pipe 202, a static sliding block 203, a movable sliding block 204 and a spring button 205.

Detailed Description

The utility model is further described below with reference to the drawings and specific embodiments.

As shown in fig. 6 and 7, an upright post 200 comprises a middle pipe 201, an inner pipe 202 and sliding blocks, wherein the middle pipe 201 and the inner pipe 202 are square pipes, the sliding blocks comprise a static sliding block 203 relatively fixed with the inner pipe 202 and a movable sliding block 204 relatively fixed with the middle pipe 201, the movable sliding block 204 is sleeved outside the inner pipe 202 in an annular structure, the number of the static sliding blocks 203 is four, the four static sliding blocks are respectively arranged on four outer side walls of the inner pipe 202, and the two oppositely arranged static sliding blocks 203 are clamped with the inner pipe 202 through a clamping structure.

Example 1:

as shown in fig. 1 to 7, an automatic upright column assembling mechanism comprises a fixing frame 1, a sliding frame 2 vertically and slidably connected to the fixing frame 1, a sliding block clamping jaw assembly 3, an inner pipe clamping jaw assembly 5 and a lifting mechanism 6, and a middle pipe clamping jaw assembly 4 mounted on the sliding frame 2, wherein the sliding block clamping jaw assembly 3 is arranged between the middle pipe clamping jaw assembly 4 and the inner pipe clamping jaw assembly 5, and the lifting mechanism 6 is used for driving the sliding frame 2 to lift so that the middle pipe clamping jaw assembly 4 can be close to or far away from the sliding block clamping jaw assembly 3.

In the above technical solution, the inner pipe clamping jaw assembly 5 clamps the inner pipe 202 and fixes the inner pipe 202, the slide block clamping jaw assembly 3 can fix the slide block on the outer side wall of the inner pipe 202, the middle pipe clamping jaw assembly 4 clamps the middle pipe 201, the lifting mechanism 6 drives the sliding frame 2 to move up and down, and drives one end of the middle pipe 201 to be sleeved on the outer side of the inner pipe 202, and the slide block is connected to the middle pipe 201. During the sleeving of the middle tube 201 on the inner tube 202, the sliding block clamping jaw assembly 3 releases the sliding block, so that the sliding block clamping jaw assembly 3 is prevented from interfering with the middle tube 201. According to the technical scheme, the upright post 200 can be automatically assembled, the assembly mechanism can be started only by feeding the middle pipe 201, the inner pipe 202 and the sliding block into place through the feeding mechanism, all the components are clamped and then assembled into a whole, and compared with manual assembly, the efficiency is higher, the assembly cost is lower, and the consistency of assembled products is higher.

Specifically, the lifting mechanism 6 comprises a driving motor 6.1 and a screw-nut mechanism 6.2, and the sliding frame 2 and the fixed frame 1 are in sliding connection through a guide rail sliding block 7 structure.

The clamping center of the sliding block clamping jaw assembly 3, the clamping center of the middle pipe clamping jaw assembly 4 and the clamping center of the inner pipe clamping jaw assembly 5 are positioned in the same vertical plane. The scheme can align the clamping centers of all the components of the upright post 200, is convenient for assembly, and improves the accuracy of the assembled components. After the clamping jaw assembly clamps the component, the clamping center of the clamping jaw assembly coincides with the center of the clamped component.

Preferably, as shown in fig. 5, the fixing frame 1 is provided with a centering clamping jaw assembly 8, the centering clamping jaw assembly 8 comprises a centering clamping jaw and a roller 8.1 rotatably arranged on the centering clamping jaw, and the clamping center of the centering clamping jaw assembly 8 and the clamping center of the sliding block clamping jaw assembly 3 are positioned in the same vertical plane.

In the above technical scheme, the centering clamping jaw assembly 8 clamps the middle pipe 201 and can be matched with the middle pipe clamping jaw assembly 4, so that the center position of the middle pipe 201 is always kept stable and unchanged in the moving process, and the roller 8.1 enables the middle pipe 201 to move up and down relative to the centering clamping jaw assembly 8. The rotation axis of the roller 8.1 is arranged horizontally. The centering clamping jaw is a clamping jaw cylinder 8.2.

As shown in fig. 4, the middle pipe clamp jaw assembly 4 includes a middle pipe clamp jaw 4.1, a clamping groove 4.2 is provided on the middle pipe clamp jaw 4.1, and a limiting block 4.3 is provided at the upper end of the clamping groove 4.2.

In the above technical scheme, when the middle pipe clamp claw 4.1 clamps the middle pipe 201, the middle pipe 201 is located in the clamping groove 4.2, and the limiting block 4.3 abuts against the upper end of the middle pipe 201, so that the middle pipe 201 can be prevented from sliding upwards relative to the middle pipe clamp claw 4.1 in the downward moving process.

Specifically, as shown in fig. 2 and 3, the sliding block clamping jaw assembly 3 includes a traversing rack 3.1 transversely slidably connected to the fixing rack 1, a first linear driver 3.2 for driving the traversing rack 3.1 to slide, and a supporting block 3.3 fixed on the traversing rack 3.1, where the supporting block 3.3 is used for supporting the lower end face of the moving sliding block 204. The first linear drive 3.2 is connected to the holder 1.

In the above technical solution, when the first linear driver 3.2 drives the supporting block 3.3 to move and makes the supporting block 3.3 support the lower end surface of the moving slide block 204, the moving slide block 204 may be kept motionless during the downward movement of the middle pipe 201, so that the upper end of the moving slide block 204 may extend into the middle pipe 201 and be clamped with the middle pipe 201. The first linear driver 3.2 may also drive the supporting block 3.3 to move and separate the supporting block 3.3 from the moving slide block 204, so as to facilitate loading and unloading.

Preferably, the number of the supporting blocks 3.3 is two, the two supporting blocks 3.3 are driven by the same first linear driver 3.2, the fixing frame 1 is provided with a positioning block 3.10, the positioning block 3.10 is arranged in the middle of the two supporting blocks 3.3, and under the action of the positioning block 3.10, the clamping center of the two supporting blocks 3.3 is kept unchanged when the two supporting blocks 3.3 are close to each other each time.

Specifically, as shown in fig. 2 and fig. 3, the slider jaw assembly 3 further includes a pressing block 3.4 that is transversely slidably connected to the traversing frame 3.1 and a second linear driver 3.5 that is used for driving the pressing block 3.4 to slide, the sliding direction of the pressing block 3.4 is perpendicular to the sliding direction of the traversing frame 3.1, and a pressing portion 3.11 that protrudes from the pressing block 3.4 and is used for pressing the latch 205 on the movable slider 204 is disposed at the lower portion of the pressing block 3.4. The second linear actuator 3.5 is connected with the traversing carriage 3.1.

In the above technical solution, the pressing portion 3.11 may press the elastic buckle 205 on the movable slider 204, so that the movable slider 204 may extend into the middle tube 201.

Preferably, the pressing part is of a U-shaped structure.

Preferably, the pressing portion 3.11 is configured to press the latch 205 on the moving slider 204, and when the pressing portion 3.11 presses the latch 205, the height of the upper end surface of the pressing portion 3.11 is lower than the height of the upper end surface of the latch 205.

In the above technical solution, when the compressing portion 3.11 compresses the latch 205, the height of the upper end surface of the compressing portion 3.11 is lower than that of the latch 205, during the assembly process, the middle tube 201 may be partially sleeved on the upper end of the latch 205, at this time, the middle tube 201 may already clamp the latch 205, so as to ensure that the latch 205 cannot pop out outwards, at this time, the middle tube 201 will not interfere with the clamping member 3.6, and then the compressing portion 3.11 is loosened, so that the middle tube 201 continues to move downwards, and the whole latch 205 extends into the middle tube 201 and is clamped with the middle tube 201.

Specifically, as shown in fig. 2 and 3, the clamping piece 3.6 and the third linear driver 3.8 for driving movement are disposed on the pressing block 3.4, and the clamping piece 3.6 is disposed above the pressing portion and is used for pressing the static slider 203. The third linear drive 3.8 is connected to the pressure block 3.4.

In the above technical solution, the clamping member 3.6 may compress the static slider 203, so as to avoid the static slider 203 falling from the inner tube 202 during the assembly process.

Preferably, the clamping piece 3.6 is used for pressing the static slider 203, and when the clamping piece 3.6 clamps the static slider 203, the height of the upper end face of the clamping piece 3.6 is lower than that of the upper end face of the static slider 203.

In the above technical solution, when the clamping member 3.6 clamps the static slider 203, the height of the upper end surface of the clamping member 3.6 is lower than that of the upper end surface of the static slider 203, during the assembly process, the middle tube 201 may be partially sleeved on the upper end of the static slider 203, at this time, the middle tube 201 may already clamp the static slider 203, so as to ensure that the static slider 203 cannot separate from the inner tube 202, at this time, the middle tube 201 cannot interfere with the clamping member 3.6, and then the clamping member 3.6 is loosened, so that the middle tube 201 continues to move downwards, and the whole static slider 203 extends into the middle tube 201.

Preferably, the lateral moving frame 3.1 is provided with an avoidance hole 3.9, and when the support block 3.3 is supported on the lower end surface of the movable sliding block 204, the avoidance hole 3.9 is located below the movable sliding block 204.

Because of a certain shake during the feeding process, the movable slider 204 may slide down along the outer wall of the inner tube 202 by a certain distance, and if the supporting block 3.3 is directly clamped, the supporting block 3.3 may clamp the movable slider 204. In the above technical scheme, the avoidance hole 3.9 can avoid a supporting piece, the supporting piece is installed on the mechanical arm, after loading is completed, the movable sliding block 204 is jacked up from bottom to top through the supporting piece, so that the movable sliding block 204 moves in place, then the supporting block 3.3 is clamped again, and after the supporting block 3.3 moves in place, the supporting piece is withdrawn.

The working process of the scheme of the embodiment is as follows: the middle tube 201, the inner tube 202 and the sliding blocks are respectively fed into position through the feeding mechanism, the middle tube 201 is clamped by the middle tube clamping jaw assembly 4 and the centering clamping jaw assembly 8, the inner tube 202 is fixed, the sliding blocks can be clamped and relatively fixed on the outer side wall of the inner tube 202 by the sliding block clamping jaw assembly 3, then the sliding frame 2 is driven to move downwards through the lifting mechanism 6, the middle tube 201 is driven to move downwards by the inner tube clamping jaw assembly 5, when the static sliding blocks 203 are partially stretched into the middle tube 201, the middle tube 201 can clamp the static sliding blocks 203, the static sliding blocks 203 are ensured not to be separated from the inner tube 202, the clamping pieces 3.6 can be loosened at the moment, then the middle tube 201 is further moved downwards, the static slide block 203 is enabled to extend into the middle tube 201 entirely, then the middle tube 201 is further moved downwards, the movable slide block 204 is enabled to extend into the middle tube 201 partially, when the elastic buckle 205 on the movable slide block 204 is also extended into the middle tube 201 partially, the middle tube 201 can clamp the elastic buckle 205, the elastic buckle 205 is guaranteed not to be outwards ejected, then the pressing part 3.11 is loosened, the middle tube 201 is enabled to move downwards, the elastic buckle 205 is enabled to extend into the middle tube 201 entirely and be clamped with the middle tube 201, then the supporting block 3.3 is opened, the middle tube 201 is enabled to move downwards for a small distance continuously, and then the middle tube clamping jaw assembly 4, the centering jaw assembly 8 and the inner tube clamping jaw assembly 5 are loosened, and the assembled upright post 200 is taken out.

In this embodiment, the first linear actuator 3.2 may be a cylinder, an electric push rod, a motor-driven screw nut mechanism, a motor-driven rack and pinion mechanism, or other common linear driving mechanisms, and is preferably a cylinder. The second linear actuator 3.5 may be a cylinder, an electric push rod, a motor-driven screw-nut mechanism, a motor-driven rack-and-pinion mechanism, or other common linear driving mechanisms, preferably a jaw cylinder. The third linear actuator 3.8 may be a cylinder, an electric push rod, a motor-driven screw-nut mechanism, a motor-driven rack-and-pinion mechanism, or other various conventional linear driving mechanisms, and is preferably a cylinder.

Claims (10)

1. The utility model provides an automatic equipment mechanism of stand, its characterized in that, including mount, vertical sliding connection in the carriage of mount, install in slider clamping jaw subassembly, inner tube clamping jaw subassembly and elevating system of mount, and install in the well pipe clamp jaw subassembly of carriage, slider clamping jaw subassembly sets up well pipe clamp jaw subassembly with between the inner tube clamping jaw subassembly, elevating system is used for driving the carriage and goes up and down, so that well pipe clamp jaw subassembly can be close to or keep away from slider clamping jaw subassembly.

2. The automatic column assembly mechanism of claim 1, wherein the center of the slide jaw assembly, the center of the middle pipe clamp jaw assembly, and the center of the inner pipe clamp jaw assembly are in the same vertical plane.

3. The automatic upright assembling mechanism according to claim 1, wherein the fixing frame is provided with a centering clamping jaw assembly, the centering clamping jaw assembly comprises a centering clamping jaw and a roller rotatably arranged on the centering clamping jaw, and the clamping center of the centering clamping jaw assembly and the clamping center of the sliding block clamping jaw assembly are positioned in the same vertical plane.

4. A post automatic assembly mechanism according to any one of claims 1 to 3, wherein the slider jaw assembly comprises a traverse frame which is laterally slidably connected to the fixed frame, a first linear driver for driving the traverse frame to slide, and a support block fixed to the traverse frame, the support block being for supporting a lower end face of the movable slider.

5. The automatic column assembling mechanism according to claim 4, wherein the slider jaw assembly further comprises a pressing block transversely slidably connected to the traverse frame and a second linear driver for driving the pressing block to slide, a sliding direction of the pressing block is perpendicular to a sliding direction of the traverse frame, and a pressing portion protruding the pressing block and for pressing the snap fastener on the movable slider is provided at a lower portion of the pressing block.

6. The automatic column assembling mechanism according to claim 5, wherein the pressing portion has a U-shaped structure.

7. The automatic column assembling mechanism according to claim 5, wherein when the pressing portion presses the snap fastener, the height of the upper end face of the pressing portion is lower than the height of the upper end face of the snap fastener.

8. The automatic column assembling mechanism according to claim 5, wherein the clamping piece and the third linear driver for driving movement are arranged on the pressing block, and the clamping piece is arranged above the pressing part and used for pressing the static sliding block.

9. The automatic column assembling mechanism according to claim 8, wherein when the clamping member clamps the stationary slide, the height of the upper end face of the clamping member is lower than the height of the upper end face of the stationary slide.

10. The automatic upright post assembling mechanism according to claim 5, wherein the traversing frame is provided with an avoiding hole, and the avoiding hole is positioned below the movable slide block when the supporting block is supported on the lower end surface of the movable slide block.