CN114576501A

CN114576501A - Intelligent factory monitoring equipment based on 5G remote intelligent control

Info

Publication number: CN114576501A
Application number: CN202210250288.2A
Authority: CN
Inventors: 沈纪云; 胡秀琴; 孙业诚
Original assignee: Lu'an Xiangchuan Technology Co ltd
Current assignee: Lu'an Xiangchuan Technology Co ltd
Priority date: 2022-03-15
Filing date: 2022-03-15
Publication date: 2022-06-03
Also published as: ZA202207022B

Abstract

The invention relates to a monitoring device, in particular to a smart factory monitoring device based on 5G remote intelligent control, which comprises a monitor, wherein a signal receiving and transmitting module used for communicating with a monitoring center through a 5G network is arranged at the tail part of the monitor; a bearing piece and an installation cover are sequentially arranged below the monitor, and a swinging mechanism is arranged between the bearing piece and the monitor; and a lifting mechanism is arranged between the mounting cover and the supporting piece, and the lifting mechanism is connected with the swinging mechanism. The lifting mechanism and the swinging mechanism are arranged and work alternately, so that the monitor can swing back and forth intermittently in one direction, and the lifting mechanism is utilized to drive the supporting piece and the monitor to lift or fall, so that the monitoring area covered by the monitor is greatly increased in a reciprocating manner; the monitor collects images and transmits the images to the monitoring center through the 5G network and the signal transceiving module.

Description

Intelligent factory monitoring equipment based on 5G remote intelligent control

Technical Field

The invention relates to monitoring equipment, in particular to intelligent factory monitoring equipment based on 5G remote intelligent control.

Background

The first guarantee for realizing intelligent manufacturing is production intelligence, namely, an intelligent factory is built, and real-time production monitoring becomes the most critical link in the production intelligence.

The real-time production monitoring is to identify the ongoing or imminent production efficiency loss in a production field by acquiring actual production data in real time and comparing process standard data, so as to comprehensively manage and improve the production efficiency.

Most of the monitoring devices currently in use have a very limited monitoring range, even if the monitoring devices are wide-angle monitors, the monitoring range is limited to the coverage area of the visual angle, the monitoring range completely depends on the visual angle of the monitor, and the limitation is large.

Disclosure of Invention

The invention aims to provide a smart factory monitoring device based on 5G remote smart control, so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

a smart factory monitoring device based on 5G remote intelligent control comprises a monitor, wherein a signal receiving and transmitting module used for communicating with a monitoring center through a 5G network is mounted at the tail of the monitor;

a bearing piece and a mounting cover are sequentially arranged below the monitor, a swinging mechanism is arranged between the bearing piece and the monitor, and the swinging mechanism is used for driving the monitor to swing back and forth intermittently;

the lifting mechanism is arranged between the mounting cover and the bearing piece and used for driving the bearing piece to intermittently lift and fall relative to the mounting cover, and the lifting mechanism is connected with the swinging mechanism.

The intelligent factory monitoring equipment based on 5G remote intelligent control as described above: the swing mechanism comprises a first full gear rotatably mounted on the bearing piece, a swing arm coaxially fixed on the first full gear, and a clamping column fixed at the eccentric position of the swing arm;

the lower part of the monitor is hinged with the top of the lifting shaft, a swinging plate is fixed on the upper part of the lifting shaft, and a clamping groove in sliding fit with the clamping column is formed in the swinging plate.

The intelligent factory monitoring equipment based on 5G remote intelligent control as described above: the lifting mechanism comprises a lifting shaft penetrating through and rotationally matched with the supporting piece, a first sleeve fixed on the mounting cover and in sliding fit with the lifting shaft, a second full gear fixed at the top of the lifting shaft and a height adjusting assembly connecting the mounting cover and the supporting piece;

the surface of the lifting shaft is provided with an embedded groove along the length direction, and the upper part of the inner wall of the first sleeve is fixed with a bulge which is clamped with the embedded groove in a sliding manner.

The intelligent factory monitoring equipment based on 5G remote intelligent control as described above: the height adjusting assembly comprises a worm connected with the first sleeve through a bidirectional transmission structure, a worm wheel rotatably arranged at the lower part of the mounting cover and meshed with the worm, a lifting gear coaxially fixed with the worm wheel, a bracket vertically penetrating through the mounting cover and in sliding fit with the mounting cover, and a third rack fixed on one side of the bracket and meshed with the lifting gear;

the worm penetrates through the mounting cover and is in running fit with the mounting cover, a penetrating opening for the bracket and the third rack to penetrate through in a sliding mode is formed in the mounting cover, and the top of the bracket is fixed with the mounting cover.

The intelligent factory monitoring equipment based on 5G remote intelligent control as described above: the bidirectional transmission structure comprises a sliding block fixed on the mounting cover, a track groove in sliding fit with the sliding block, a movable frame used for fixing the track groove, a second half gear fixed on the upper part of the first sleeve, and a first rack fixed on the inner walls of two sides of the movable frame and matched with the second half gear;

and a second rack is fixed on the outer wall of one side of the movable frame and meshed with a follow-up gear fixed on the upper part of the worm.

The intelligent factory monitoring equipment based on 5G remote intelligent control as described above: the lifting mechanism is connected with the swinging mechanism through a driving mechanism;

the driving mechanism comprises a second sleeve penetrating through and fixed with the mounting cover, the second sleeve is in transition fit with the lower part of the lifting shaft, a shaft sleeve penetrates through and fixed on the bearing piece, and the lifting shaft penetrates through the shaft sleeve and is in rotation fit with the shaft sleeve;

and a first half gear is fixed on the upper part of the shaft sleeve and drives the first half gear to be in discontinuous fit with a same full gear and a second full gear.

The intelligent factory monitoring equipment based on 5G remote intelligent control as described above: the lower part of the mounting cover is provided with a motor, the output end of the motor is connected with a driving shaft, the driving shaft penetrates through the mounting cover and is in rotating fit with the mounting cover, and the upper part of the driving shaft is connected with the shaft sleeve through a transmission part;

the lower part detachably of installation lid installs the protective housing, the surface of lift axle is provided with two rings of flanges, the axle sleeve rotates the cover and establishes two rings between the flange.

Compared with the prior art, the invention has the beneficial effects that: the lifting mechanism and the swinging mechanism work alternately, so that the monitor can swing back and forth discontinuously in one direction, the monitor pauses for a period of time when swinging to the stroke end point, the lifting mechanism is utilized to drive the bearing piece and the monitor to lift or fall in the pause period of time, the swinging mechanism drives the monitor to swing reversely when the bearing piece and the monitor lift or fall to the stroke end point, the swinging mechanism stops working again when swinging reversely to the stroke end point in the reverse direction, and the lifting mechanism drives the bearing piece and the monitor to fall or lift, so that the monitoring area covered by the monitor is greatly increased by reciprocating; the monitor collects images and transmits the images to the monitoring center through the 5G network and the signal transceiving module.

Drawings

Fig. 1 is a schematic structural diagram of a smart factory monitoring device based on 5G remote smart control.

FIG. 2 is a schematic diagram of another aspect of an intelligent plant monitoring apparatus based on 5G remote intelligent control.

Fig. 3 is a schematic structural diagram of a smart factory monitoring device based on 5G remote intelligent control after a protection box is removed.

FIG. 4 is a schematic structural diagram of a smart factory monitoring device based on 5G remote intelligent control, in which a support member and an installation cover are detached.

Fig. 5 is an explosion diagram of a swing mechanism in a smart factory monitoring device based on 5G remote smart control.

Fig. 6 is a schematic view of the structure of fig. 5 in another orientation.

Fig. 7 is a schematic structural diagram of a lifting mechanism in an intelligent plant monitoring device based on 5G remote intelligent control.

Fig. 8 is an exploded view of a movable frame and a mounting cover in a smart factory monitoring device based on 5G remote smart control.

Fig. 9 is a schematic view of the structure of fig. 8 in another orientation.

In the figure: 1-a protective box; 2-installing a cover; 3-a support member; 4-a monitor; 5-a swing plate; 6-a clamping groove; 7-a motor; 8-driving shaft; 9-a transmission member; 10-shaft sleeve; 11-a lifting shaft; 12-a first half gear; 13-full gear number one; 14-a swing arm; 15-clamping column; 16-second full gear; 17-lifting the shaft; 18-a first sleeve; 19-a second sleeve; 20-caulking groove; 21-bulge; 22-second half gear; 23-a movable frame; 24-rack one; 25-a track groove; 26-a slide block; 27-second rack; 28-a follower gear; 29-a worm; 30-a worm gear; 31-a lifting gear; 32-third rack; 33-bracket.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1 to 9, as an embodiment of the present invention, the smart factory monitoring device based on 5G remote intelligent control includes a monitor 4, wherein a signal transceiver module for communicating with a monitoring center through a 5G network is installed at a tail of the monitor 4;

a supporting piece 3 and a mounting cover 2 are sequentially arranged below the monitor 4, a swinging mechanism is arranged between the supporting piece 3 and the monitor 4, and the swinging mechanism is used for driving the monitor 4 to swing back and forth intermittently;

a lifting mechanism is arranged between the mounting cover 2 and the supporting piece 3, the lifting mechanism is used for driving the supporting piece 3 to intermittently lift and fall relative to the mounting cover 2, and the lifting mechanism is connected with the swinging mechanism;

when the swing mechanism drives the monitor 4 to swing towards one direction to the stroke end point, the swing mechanism stops working, and the lifting mechanism drives the supporting piece 3 and the monitor 4 to lift or fall;

when the lifting mechanism drives the supporting piece 3 and the monitor 4 to lift up or fall down to the stroke end point, the lifting mechanism stops working, and the swinging mechanism drives the monitor 4 to swing in the opposite direction.

The lifting mechanism and the swinging mechanism are arranged and work alternately, so that the monitor 4 can swing back and forth discontinuously towards one direction, the time is paused for a period of time when the monitor 4 swings to the stroke end point, the lifting mechanism is utilized to drive the bearing piece 3 and the monitor 4 to lift up or fall down in the paused time period, the swinging mechanism drives the monitor 4 to swing reversely when the bearing piece 3 and the monitor 4 lift up or fall down to the stroke end point, the swinging mechanism stops working again when the bearing piece 3 and the monitor 4 swing reversely to the stroke end point in the reverse direction, the lifting mechanism drives the bearing piece 3 and the monitor 4 to fall down or lift up, and the reciprocating mode greatly increases the monitoring area covered by the monitor 4; the monitor 4 collects images and transmits the images to the monitoring center through the 5G network and the signal transceiving module.

As a further scheme of the present invention, the swing mechanism includes a first full gear 13 rotatably mounted on the support 3, a swing arm 14 coaxially fixed on the first full gear 13, and a clamp column 15 fixed at an eccentric position of the swing arm 14;

the lower part of the monitor 4 is hinged with the top of the lifting shaft 11, the upper part of the lifting shaft 11 is fixed with a swinging plate 5, and the swinging plate 5 is provided with a clamping groove 6 which is in sliding fit with the clamping column 15;

it should be noted that a rotating shaft is fixed on the lower portion of the monitor 4, a rubber damping sleeve is fixed on the top of the lifting shaft 11, the rotating shaft is in running fit with the rubber damping sleeve, the rotating center of the swing arm 14 is located at the center of the clamping groove 6, and the length of the clamping groove 6 is not less than the rotating diameter of the clamping column 15.

When the first full gear 13 rotates, the swing arm 14 is driven to rotate, the swing arm 14 drives the clamping column 15 to do circular motion, and the clamping column 15 in the circular motion is matched with the clamping groove 6, so that the swing plate 5 drives the lifting shaft 11 to rotate back and forth, and further drives the monitor 4 to swing back and forth;

in addition, the included angle between the monitor 4 and the swing plate 5 can be adjusted under the action of the rubber damping sleeve and the rotating shaft, and then the pitching angle of the monitor 4 is adjusted.

As a further aspect of the present invention, the lifting mechanism includes a lifting shaft 17 penetrating through and rotationally engaged with the support 3, a first sleeve 18 fixed on the mounting cover 2 and slidably engaged with the lifting shaft 17, a second full gear 16 fixed on the top of the lifting shaft 17, and a height adjusting assembly connecting the mounting cover 2 and the support 3;

the surface of the lifting shaft 17 is provided with an embedded groove 20 along the length direction, and the upper part of the inner wall of the first sleeve 18 is fixed with a bulge 21 which is clamped with the embedded groove 20 in a sliding way;

the lifting shaft 17 is driven to rotate along with the rotation of the second full gear 16, the lifting shaft 17 drives the first sleeve 18 to rotate by means of the cooperation of the embedded groove 20 and the protrusion 21, and the first sleeve 18 drives the supporting piece 3 to lift or fall relative to the mounting cover 2 through the height adjusting component.

Due to the arrangement of the protrusion 21 and the caulking groove 20, when the support member 3 is lifted or dropped relative to the mounting cover 2, the protrusion 21 slides up and down along the caulking groove 20, and in the relative sliding process of the protrusion and the caulking groove, the lifting shaft 17 and the first sleeve 18 do not rotate relatively;

when the height adjusting assembly drives the lifting piece 3 to lift or fall relative to the mounting cover 2, the lifting shaft 11 is utilized to drive the monitor 4 to lift or fall, so that the height of the monitor 4 is changed.

As a further aspect of the present invention, the height adjusting assembly includes a worm 29 connected to the first sleeve 18 through a bidirectional transmission structure, a worm wheel 30 rotatably disposed at a lower portion of the mounting cover 2 and engaged with the worm 29, a lifting gear 31 coaxially fixed with the worm wheel 30, a bracket 33 vertically penetrating the mounting cover 2 and slidably engaged therewith, and a third rack 32 fixed at one side of the bracket 33 and engaged with the lifting gear 31;

the worm 29 penetrates through the mounting cover 2 and is in running fit with the mounting cover 2, a penetrating opening for the bracket 33 and the third rack 32 to pass through is formed in the mounting cover 2 in a sliding mode, and the top of the bracket 33 is fixed with the mounting cover 2.

In the embodiment, during the process that the first sleeve 18 rotates along with the lifting shaft 17, the worm 29 is driven to rotate by the bidirectional transmission structure, the worm 29 drives the worm wheel 30 to rotate, the worm wheel 30 drives the lifting gear 31 to synchronously rotate, and then the third rack 32 and the bracket 33 are driven to pass through the through hole to lift or fall, and finally the bracket 33 drives the support member 3 to lift or fall.

As a further aspect of the present invention, the bidirectional transmission structure includes a sliding block 26 fixed on the mounting cover 2, a rail groove 25 in sliding fit with the sliding block 26, a movable frame 23 for fixing the rail groove 25, a second half gear 22 fixed on the upper portion of the first sleeve 18, and a first rack 24 fixed on the inner walls of both sides of the movable frame 23 and matched with the second half gear 22;

a second rack 27 is fixed on the outer wall of one side of the movable frame 23, and the second rack 27 is meshed with a follow-up gear 28 fixed on the upper part of a worm 29;

specifically, the movable frame 23 is perpendicular to the length direction of the mounting cover 2, and an abdicating groove for the first sleeve 18 to pass through and move is formed in the center of the movable frame 23.

The second half gear 22 is driven to rotate when the first sleeve 18 rotates, and when the second half gear 22 is meshed with a first rack 24 on the inner wall of one side of the movable frame 23, the movable frame 23 is driven to slide along a direction vertical to the length of the mounting cover 2 under the action of a sliding block 26 and a track groove 25; when the second half gear 22 is meshed with the first rack 24 on the inner wall of the other side of the movable frame 23, the movable frame 23 is driven to slide along the other direction vertical to the length of the mounting cover 2 under the action of the slide block 26 and the track groove 25;

when the movable frame 23 drives the second rack 27 to move towards one direction, the second rack 27 drives the follower gear 28 to rotate forward, and further drives the worm 29 to rotate forward; when the movable frame 23 drives the second rack 27 to move towards the other direction, the second rack 27 drives the follower gear 28 to rotate reversely, and further drives the worm 29 to rotate positively and negatively;

when the worm 29 rotates forwards, the worm wheel 30 is driven to rotate clockwise, and at the moment, the worm wheel 30 drives the lifting gear 31 to rotate clockwise, so that the third rack 32 and the bracket 33 are driven to fall, and finally the support piece 3 is driven to fall;

when the worm 29 rotates reversely, the worm wheel 30 is driven to rotate anticlockwise, at the moment, the worm wheel 30 drives the lifting gear 31 to rotate anticlockwise, so that the third rack 32 and the bracket 33 are driven to lift upwards, and finally the support piece 3 is driven to lift upwards.

As a still further scheme of the present invention, the lifting mechanism is connected with the swing mechanism through a driving mechanism;

the driving mechanism comprises a second sleeve 19 which penetrates through the mounting cover 2 and is fixed with the mounting cover, the second sleeve 19 is in transition fit with the lower part of the lifting shaft 11, a shaft sleeve 10 penetrates through and is fixed on the supporting piece 3, and the lifting shaft 11 penetrates through the shaft sleeve 10 and is in rotation fit with the shaft sleeve;

a first half gear 12 is fixed on the upper part of the shaft sleeve 10 and drives the first half gear 12 to be in discontinuous fit with a first full gear 13 and a second full gear 16;

when the toothed part on the first half gear 12 is meshed with the first full gear 13, the toothed part on the first half gear 12 is disengaged from the second full gear 16;

when the toothed portion on the first half gear 12 is engaged with the second full gear 16, the toothed portion on the first half gear 12 is disengaged from the first full gear 13.

In addition, the specifications of the first half gear 12, the first full gear 13 and the second full gear 16 are the same, that is, the reference circle radius and the modulus are the same, so when the first half gear 12 rotates for one circle, the first full gear 13 is driven to rotate for half a circle, and then the second full gear 16 is driven to rotate for half a circle;

the first full gear 13 rotates for a half circle and drives the swinging plate 5 to swing for a complete stroke in one direction through the swinging arm 14 and the clamping column 15; the second full gear 13 rotates for a half circle and drives the supporting piece 3 and the monitor 4 to lift or fall for a complete stroke through the lifting shaft 17 and the height adjusting component;

after the monitor 4 deflects in one direction for a complete stroke, the toothed part on the first half gear 12 is separated from the first full gear 13, so that the first half gear stops for a period of time, and the second full gear 16 drives the supporting part 3 and the monitor 4 to lift or fall for a complete stroke by virtue of the height adjusting assembly in the stopping period, so that the height of the monitor 4 is adjusted up and down while the monitor 4 swings back and forth, and the monitoring area of the monitor 4 is enlarged.

As a further scheme of the present invention, a motor 7 is installed at the lower part of the installation cover 2, the output end of the motor 7 is connected with a driving shaft 8, the driving shaft 8 passes through the installation cover 2 and is in rotating fit with the installation cover, and the upper part of the driving shaft 8 is connected with the shaft sleeve 10 through a transmission member 9;

the lower part of the mounting cover 2 is detachably provided with a protective box 1, the surface of the lifting shaft 11 is provided with two circles of flanges, and the shaft sleeve 10 is rotatably sleeved between the two circles of flanges.

The motor 7 can drive the driving shaft 8 to rotate, and the rotating driving shaft 8 drives the shaft sleeve 10 to rotate by means of the transmission piece 9, so that the first half gear 12 can rotate uninterruptedly finally.

In addition, the provision of two rings of flanges prevents misalignment along the axis between the sleeve 10 and the lift shaft 11.

The above embodiments are exemplary rather than limiting, and embodiments of the invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof.

Claims

1. A smart factory monitoring device based on 5G remote smart control is characterized by comprising a monitor (4), wherein a signal transceiving module used for communicating with a monitoring center through a 5G network is installed at the tail of the monitor (4);

a supporting piece (3) and a mounting cover (2) are sequentially arranged below the monitor (4), a swinging mechanism is arranged between the supporting piece (3) and the monitor (4), and the swinging mechanism is used for driving the monitor (4) to swing back and forth intermittently;

the lifting mechanism is arranged between the mounting cover (2) and the bearing piece (3), and is used for driving the bearing piece (3) to intermittently lift and fall relative to the mounting cover (2), and the lifting mechanism is connected with the swinging mechanism.

2. A smart factory monitoring device based on 5G remote smart control according to claim 1, wherein the swing mechanism comprises a first full gear (13) rotatably mounted on the support member (3), a swing arm (14) coaxially fixed on the first full gear (13), and a clamp column (15) fixed at the eccentric position of the swing arm (14);

the lower part of the monitor (4) is hinged to the top of the lifting shaft (11), the upper part of the lifting shaft (11) is fixed with a swing plate (5), and a clamping groove (6) which is matched with the clamping column (15) in a sliding mode is formed in the swing plate (5).

3. A smart factory monitoring device based on 5G remote smart control according to claim 2, wherein the lifting mechanism comprises a lifting shaft (17) penetrating through and rotationally engaged with the support member (3), a first sleeve (18) fixed on the mounting cover (2) and slidably engaged with the lifting shaft (17), a second full gear (16) fixed on the top of the lifting shaft (17), and a height adjusting component connecting the mounting cover (2) and the support member (3);

an embedding groove (20) is formed in the surface of the lifting shaft (17) along the length direction of the lifting shaft, and a protrusion (21) which is clamped with the embedding groove (20) in a sliding mode is fixed on the upper portion of the inner wall of the first sleeve (18).

4. A smart factory monitoring device based on 5G remote smart control according to claim 3, wherein the height adjusting assembly comprises a worm (29) connected with the first sleeve (18) through a bidirectional transmission structure, a worm wheel (30) rotatably disposed at the lower part of the mounting cover (2) and engaged with the worm (29), a lifting gear (31) coaxially fixed with the worm wheel (30), a bracket (33) vertically passing through the mounting cover (2) and slidably engaged therewith, and a third rack (32) fixed at one side of the bracket (33) and engaged with the lifting gear (31);

the worm (29) penetrates through the mounting cover (2) and is in running fit with the mounting cover, a penetrating opening for the bracket (33) and the third rack (32) to penetrate through in a sliding mode is formed in the mounting cover (2), and the top of the bracket (33) is fixed with the mounting cover (2).

5. A smart factory monitoring device based on 5G remote smart control according to claim 4, wherein the bidirectional transmission structure comprises a sliding block (26) fixed on the mounting cover (2), a track groove (25) in sliding fit with the sliding block (26), a movable frame (23) for fixing the track groove (25), a second half gear (22) fixed on the upper part of the first sleeve (18), and a first rack (24) fixed on the inner walls of the two sides of the movable frame (23) and matched with the second half gear (22);

a second rack (27) is fixed on the outer wall of one side of the movable frame (23), and the second rack (27) is meshed with a follow-up gear (28) fixed on the upper portion of a worm (29).

6. The intelligent factory monitoring equipment based on 5G remote intelligent control is characterized in that the lifting mechanism is connected with the swinging mechanism through a driving mechanism;

the driving mechanism comprises a second sleeve (19) which penetrates through the mounting cover (2) and is fixed with the mounting cover, the second sleeve (19) is in transition fit with the lower part of the lifting shaft (11), a shaft sleeve (10) penetrates through and is fixed on the supporting piece (3), and the lifting shaft (11) penetrates through the shaft sleeve (10) and is in rotation fit with the shaft sleeve;

a first half gear (12) is fixed on the upper portion of the shaft sleeve (10) and drives the first half gear (12) to be in discontinuous fit with a first full gear (13) and a second full gear (16).

7. A smart factory monitoring device based on 5G remote smart control according to claim 6, wherein a motor (7) is installed at the lower part of the installation cover (2), the output end of the motor (7) is connected with a driving shaft (8), the driving shaft (8) passes through the installation cover (2) and is in rotating fit with the installation cover, and the upper part of the driving shaft (8) is connected with the shaft sleeve (10) through a transmission piece (9);

the lower part of the mounting cover (2) is detachably provided with a protective box (1), the surface of the lifting shaft (11) is provided with two circles of flanges, and the shaft sleeve (10) is rotatably sleeved between the two circles of flanges.