CN114405022B - Energy-saving built-in stage suspender device based on traceability - Google Patents

Abstract

The application discloses a traceable energy-saving built-in stage suspender device, which comprises a base and an automatic stage suspender maintenance system, and is characterized in that: the novel oil-saving device comprises a base, wherein a connecting plate is fixed on one side of the base, a supporting cylinder and a connecting shaft are fixed on the left side of the connecting plate, the connecting shaft is located inside the supporting cylinder, a motor is fixed on the left side of the connecting shaft, a speed reducer is fixed on an output shaft of the motor, a winding drum is fixed on the left side of the output shaft of the speed reducer, the right side of the winding drum is connected with the connecting plate through a bearing, the winding drum is sleeved on the outer surface of the supporting cylinder, expansion plates are fixed on the upper side and the lower side of the supporting cylinder, annular plates are fixed at the tail ends of the expansion plates, the annular plates are in contact with the surface of the motor, an oil cavity is formed in the winding drum, a plurality of oil holes are formed in the bottom of the winding drum, and the oil holes penetrate through the oil cavity.

Description

Energy-saving built-in stage suspender device based on traceability

Technical Field

The application is applied to the background of a stage suspender device and the name is an energy-saving built-in stage suspender device based on traceability.

Background

The stage suspender is a tool for suspending lamps and lanterns and scenery in the places such as movie theatres, auditoriums, clubs, concert halls, multifunctional halls, gymnasiums and the like, is a cross rod for suspending various background cloth or curtains, penetrates through the whole stage, can be lifted, is suspended at a position above the stage which cannot be seen by spectators at ordinary times, and is lowered only when the stage is arranged so as to fix a suspended object.

However, existing stage boom devices fall into two main categories: vertical and horizontal, both expose motor, speed reducer outside, occupation space is big, along with the miniaturization in theatre, multi-functional hall, traditional jib machine has unable to satisfy the demand, and the inside lubrication that is difficult to maintain of current stage jib device, and lead to inside easy damage and improper operation.

Therefore, it is necessary to provide a traceable energy-saving built-in stage boom device, which can achieve the effects of saving space and automatic lubrication and maintenance.

Disclosure of Invention

The application aims to provide a traceable energy-saving built-in stage suspender device so as to solve the problems in the background technology.

In order to solve the technical problems, the application provides the following technical scheme: the utility model provides an energy-conserving built-in stage jib device based on can track, contains base and stage jib automatic maintenance system, its characterized in that: one side of base is fixed with the connecting plate, the left side of connecting plate is fixed with a support section of thick bamboo and connecting axle, the connecting axle is located the inside of supporting a section of thick bamboo, the left side of connecting axle is fixed with the motor, the output shaft of motor is fixed with the speed reducer, the left side output shaft of speed reducer is fixed with the reel, the right side and the connecting plate of reel are the bearing connection, the reel cover is at the surface of supporting a section of thick bamboo.

In one embodiment, the upper and lower both sides of supporting cylinder are fixed with the expansion plate, the end of expansion plate all is fixed with the annular plate, annular plate and the surface contact of motor, the oil pocket has been seted up to the inside of reel, a plurality of oilholes have been seted up to the bottom of reel, the oilhole runs through with the oil pocket mutually, the junction of oilhole and oil pocket is connected with the valve, the inside sliding connection of connecting plate has the circular arc board.

In one embodiment, the automatic stage boom maintenance system comprises a detection module, a logic judgment module and a maintenance module, wherein the detection module comprises an ejection submodule, a distance detection submodule and a pressure sensor, the logic judgment module comprises an analysis submodule, a telescopic submodule, a switch submodule and a prompt submodule, the ejection submodule is positioned at one side of the inside of the connecting plate, which is close to the arc plate, the distance detection submodule is positioned at the left side of the connecting plate, the pressure sensor is positioned at one side of the annular plate, which is close to the motor, the telescopic submodule is electrically connected with the telescopic plate, and the switch submodule is electrically connected with the valve.

In one embodiment, the detection module and the logic judgment module include the following specific operation steps:

a1, starting a motor to work, and simultaneously starting a speed reducer to work, so that the speed reducer drives a winding drum to rotate;

a2, because a gap is reserved between the winding drum and the supporting drum, the arc plate is ejected out from the inside of the connecting plate through the operation of the ejection submodule, then enters the gap, the moving distance of the arc plate in the gap is detected through the distance detection submodule, a signal is transmitted to the analysis submodule, and whether rust exists between the winding drum and the supporting drum or not is analyzed;

a3, detecting the pressure of the motor on the annular plate through a pressure sensor, and judging the shaking degree of the motor;

and A4, transmitting the signals to an analysis sub-module, and judging the working efficiency of the winding drum.

In one embodiment, the A3 includes the following specific operation steps:

a31, when the pressure sensor detects that the pressure of the motor to the annular plate is a constant value, the motor is not rocked;

a32, when the pressure sensor detects that the pressure of the motor to the annular plate is larger than a constant value, the motor starts to shake.

In one embodiment, the A4 includes the following specific operation steps:

a41, when rust is not generated between the winding drum and the supporting drum and the motor is not swayed, the working efficiency of the winding drum is high;

a42, when the winding drum and the supporting cylinder do not rust and the motor shakes, or when the winding drum and the supporting cylinder rust and the motor does not shake, the working efficiency of the winding drum is represented as a middle level;

a43, when rust is generated between the winding drum and the supporting drum, and the motor shakes, the working efficiency of the winding drum is low.

In one embodiment, the maintenance module includes a blower sub-module, a temperature sensor and a calculation sub-module, the temperature sensor being located inside the support cylinder and outside the drum, respectively, the blower sub-module being located on the left inner wall of the drum.

In one embodiment, the maintenance module comprises the following specific operation steps:

s1, detecting the indoor temperature and the temperature of the supporting cylinder through a temperature sensorTransmitting signals to a calculation sub-module to judge the temperature difference between the indoor temperature and the supporting cylinder, W _{Support frame} -W _{Outer part} =p, where W _{Support frame} To support the temperature of the cylinder surface, W _{Outer part} The temperature in the room is the temperature difference between the indoor temperature and the supporting cylinder, the temperature is the temperature of centigrade, when 0<When P is less than or equal to 2, the temperature difference between the indoor and the supporting cylinder at the same time is proved to be small, so that the heat exchange speed is low, the heat dissipation is slow, and when P is>2, the temperature difference between the indoor and the supporting cylinder at the same time is proved to be large, so that the hot gas exchange speed is high, and the heat dissipation is high;

s2, when the heat dissipation is slow, transmitting a signal to the air blowing sub-module.

Compared with the prior art, the application has the following beneficial effects: according to the application, the prompting submodule is arranged, when rust exists between the winding drum and the supporting drum, and the motor shakes, the working efficiency of the winding drum is low, and signals are transmitted to the prompting submodule, so that the prompting submodule alarms, and a worker can know the condition of the stage suspender device in advance.

Drawings

The technical solution and other advantageous effects of the present application will be made apparent by the following detailed description of the specific embodiments of the present application with reference to the accompanying drawings.

In the drawings:

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

FIG. 2 is an illustration of the overall cross-sectional structural intent of the present application;

FIG. 3 is a side view of the present application showing a web;

FIG. 4 is a schematic support cylinder two-dimensional view of the present application;

FIG. 5 is a schematic view of the automatic stage boom maintenance system of the present application;

in the figure: 1. a base; 2. a connecting plate; 3. a support cylinder; 4. a connecting shaft; 5. a motor; 6. a speed reducer; 7. a reel; 8. an oil chamber; 9. an oil hole; 10. a telescoping plate; 11. an annular plate; 12. and (3) an arc plate.

Detailed Description

The following disclosure provides many different embodiments, or examples, for implementing different features of the application. In order to simplify the present disclosure, components and arrangements of specific examples are described below. They are, of course, merely examples and are not intended to limit the application. Furthermore, the present application may repeat reference numerals and/or letters in the various examples, which are for the purpose of brevity and clarity, and which do not themselves indicate the relationship between the various embodiments and/or arrangements discussed. In addition, the present application provides examples of various specific processes and materials, but one of ordinary skill in the art will recognize the application of other processes and/or the use of other materials.

Referring to fig. 1-5, the present application provides the following technical solutions: the utility model provides an energy-conserving built-in stage jib device based on can track, contains base 1 and stage jib automatic maintenance system, its characterized in that: one side of base 1 is fixed with connecting plate 2, and the left side of connecting plate 2 is fixed with support section of thick bamboo 3 and connecting axle 4, and connecting axle 4 is located the inside of support section of thick bamboo 3, and connecting axle 4 is concentric state with support section of thick bamboo 3, and the left side of connecting axle 4 is fixed with motor 5, and the output shaft of motor 5 is fixed with speed reducer 6, and motor 5 is concentric state with speed reducer 6, and the left side output shaft of speed reducer 6 is fixed with reel 7, and the right side and the connecting plate 2 of reel 7 are the bearing connection, and the reel 7 cover is at the surface of support section of thick bamboo 3.

The upper and lower both sides of supporting cylinder 3 are fixed with expansion plate 10, and the end of expansion plate 10 all is fixed with annular plate 11, and annular plate 11 and motor 5's surface contact, and oil pocket 8 has been seted up to the inside of reel 7, and a plurality of oilholes 9 have been seted up to the bottom of reel 7, and oilhole 9 runs through with oil pocket 8 mutually, and the junction of oilhole 9 and oil pocket 8 is connected with the valve, and the inside sliding connection of connecting plate 2 has circular arc board 12.

The automatic stage suspender maintenance system comprises a detection module, a logic judgment module and a maintenance module, wherein the detection module comprises an ejection submodule, a distance detection submodule and a pressure sensor, the logic judgment module comprises an analysis submodule, a telescopic submodule, a switch submodule and a prompt submodule, the ejection submodule is positioned at one side of the inner part of the connecting plate 2, which is close to the arc plate 12, the distance detection submodule is positioned at the left side of the connecting plate 2, the pressure sensor is positioned at one side of the annular plate 11, which is close to the motor 5, the telescopic submodule is electrically connected with the telescopic plate 10, and the switch submodule is electrically connected with the valve.

The ejection submodule is used for controlling the arc plates 12 to move between the connecting plates 2, the distance detection submodule is used for detecting the moving distance of the arc plates 12, the pressure sensor is used for detecting the pressure of the annular plates 11 when the motor 5 rotates, the analysis submodule is used for analyzing the working efficiency of the winding drum 7, the expansion submodule is used for controlling the expansion plate 10 to expand and contract, the switch submodule is used for controlling the valve to open or close, and the prompting submodule is used for alarming effect.

The detection module and the logic judgment module comprise the following specific operation steps:

a1, starting a motor 5 to work, and simultaneously starting a speed reducer 6 to work, so that the speed reducer 6 drives a winding drum 7 to rotate;

a2, because a gap is reserved between the winding drum 7 and the supporting cylinder 3, the arc plate 12 is ejected out of the connecting plate 2 through the operation of the ejection submodule, then enters the gap, the moving distance of the arc plate 12 in the gap is detected through the distance detection submodule, a signal is transmitted to the analysis submodule, whether rust exists between the winding drum 7 and the supporting cylinder 3 is analyzed, when the distance of the arc plate 12 entering the gap is greater than or equal to 80% of the length of the supporting cylinder 3, the arc plate 12 is smooth, and when the distance of the arc plate 12 entering the gap is smaller than 80% of the length of the supporting cylinder, the arc plate 12 is rusted on two side walls of the gap, so that a bump exists;

a3, detecting the pressure of the motor 5 on the annular plate 11 through a pressure sensor, and judging the shaking degree of the motor 5;

and A4, a signal transmission analysis sub-module is used for judging the working efficiency of the winding drum 7 and carrying out corresponding processing.

A3 comprises the following specific operation steps:

a31, when the pressure sensor detects that the pressure of the motor 5 to the annular plate 11 is a constant value, the motor 5 does not shake;

a32, when the pressure sensor detects that the pressure of the motor 5 to the annular plate 11 is larger than a constant value, the motor 5 starts to shake, and the rotating quality of the winding drum 7 can be affected.

A4 comprises the following specific operation steps:

a41, when no rust exists between the winding drum 7 and the supporting drum 3 and the motor 5 does not shake, the working efficiency of the winding drum 7 is high;

a42, when the winding drum 7 and the supporting cylinder 3 do not rust and the motor 5 shakes, or when the winding drum 7 and the supporting cylinder 3 rust and the motor 5 does not shake, the working efficiency of the winding drum 7 is the middle level, when the winding drum 7 and the supporting cylinder 3 do not rust and the motor 5 shakes, a signal is transmitted to the telescopic sub-module, the telescopic plate 10 is controlled to extend, and the motor 5 is clamped up and down by the annular plate 11, so that the stability of the motor is improved; when rust occurs between the winding drum 7 and the supporting drum 3 and the motor 5 does not shake, a signal is transmitted to the switch submodule to control the valve to be opened, so that oil in the oil cavity 8 flows to a gap through the oil hole 9, friction between the winding drum 7 and the supporting drum 3 due to rust and protruding blocks is reduced, and the working efficiency of the winding drum 7 is improved;

a43, rust when between reel 7 and support section of thick bamboo 3, and motor 5 rocks, indicate that the work efficiency of reel 7 is low-level, give the suggestion submodule with signal transmission, make its warning, the staff of being convenient for knows the condition of stage jib device in advance.

The maintenance module comprises a blowing submodule, a temperature sensor and a calculating submodule, wherein the temperature sensor is respectively positioned inside the supporting cylinder 3 and outside the winding drum 7, and the blowing submodule is positioned on the left inner wall of the winding drum 7;

the blowing submodule is used for blowing, the temperature sensor is used for detecting the temperature of the surface of the supporting cylinder 3, and the calculating submodule is used for judging the use quality of the stage suspender device.

The maintenance module comprises the following specific operation steps:

s1, detecting the indoor temperature and the temperature of the supporting cylinder 3 through a temperature sensor, transmitting signals to a calculation submodule, judging the temperature difference between the indoor temperature and the supporting cylinder 3, and W _{Support frame} -W _{Outer part} =p, where W _{Support frame} To support the temperature of the surface of the cylinder 3, W _{Outer part} The temperature in the room is the temperature difference between the indoor temperature and the supporting cylinder 3, the temperature is the temperature of centigrade, when 0<When P is less than or equal to 2, the temperature difference between the indoor and the supporting cylinder 3 at the same time is small, becauseThe low heat exchange speed indicates low heat dissipation, when P>2, the temperature difference between the indoor and the supporting cylinder 3 at the same time is proved to be large, so that the hot gas exchange speed is high, and the heat dissipation is high;

s2, when the heat dissipation is slow, signals are transmitted to the blowing submodule, so that the blowing submodule blows air, the air circulation in the supporting cylinder 3 can be improved, and the heat dissipation effect is improved;

the maintenance module further comprises the following specific operation steps:

when the heat dissipation is slow, and the working efficiency of the winding drum 7 is medium, the use quality of the stage suspender device is low, the step A42 and the step S2 are repeated, the working efficiency of the winding drum is improved while the heat dissipation is carried out, and the use quality of the stage suspender device can be improved.

In the description of the present application, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically connected, electrically connected or can be communicated with each other; may be directly connected, may be in communication with the interior of two elements or may be in interaction with two elements. It will be understood by those of ordinary skill in the art that the above terms are in the present application as the case may be.

The foregoing has described in detail a cleaning device provided by embodiments of the present application, and specific examples have been applied to illustrate the principles and embodiments of the present application, where the foregoing examples are only for aiding in understanding of the technical solution and core idea of the present application; those of ordinary skill in the art will appreciate that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the application.

Claims (6)

1. The utility model provides an energy-conserving built-in stage jib device based on can track, contains base (1) and stage jib automatic maintenance system, its characterized in that: one side of the base (1) is fixedly provided with a connecting plate (2), the left side of the connecting plate (2) is fixedly provided with a supporting cylinder (3) and a connecting shaft (4), the connecting shaft (4) is positioned in the supporting cylinder (3), the left side of the connecting shaft (4) is fixedly provided with a motor (5), an output shaft of the motor (5) is fixedly provided with a speed reducer (6), the left side output shaft of the speed reducer (6) is fixedly provided with a winding drum (7), the right side of the winding drum (7) is connected with the connecting plate (2) through a bearing, and the winding drum (7) is sleeved on the outer surface of the supporting cylinder (3);

the oil cylinder is characterized in that expansion plates (10) are fixed on the upper side and the lower side of the supporting cylinder (3), annular plates (11) are fixed at the tail ends of the expansion plates (10), the annular plates (11) are in contact with the surface of the motor (5), an oil cavity (8) is formed in the winding drum (7), a plurality of oil holes (9) are formed in the bottom of the winding drum (7), the oil holes (9) penetrate through the oil cavity (8), a valve is connected to the joint of the oil holes (9) and the oil cavity (8), and an arc plate (12) is connected to the inside of the connecting plate (2) in a sliding mode;

the automatic maintenance system of the stage suspender comprises a detection module, a logic judgment module and a maintenance module, wherein the detection module comprises an ejection submodule, a distance detection submodule and a pressure sensor, the logic judgment module comprises an analysis submodule, a telescopic submodule, a switch submodule and a prompt submodule, the ejection submodule is positioned at one side of the connecting plate (2) close to the arc plate (12), the distance detection submodule is positioned at the left side of the connecting plate (2), the pressure sensor is positioned at one side of the annular plate (11) close to the motor (5), the telescopic submodule is electrically connected with the telescopic plate (10), and the switch submodule is electrically connected with the valve.

2. A traceable energy-efficient built-in stage boom assembly according to claim 1, characterized in that: the detection module and the logic judgment module comprise the following specific operation steps:

a1, starting a motor (5) to work, and simultaneously starting a speed reducer (6) to work, so that the speed reducer (6) drives a winding drum (7) to rotate;

a2, because a gap is reserved between the winding drum (7) and the supporting cylinder (3), the arc plate (12) is ejected out of the connecting plate (2) through the operation of the ejection submodule, and then enters the gap, the distance detection submodule detects the moving distance of the arc plate (12) in the gap, signals are transmitted to the analysis submodule, and whether rust exists between the winding drum (7) and the supporting cylinder (3) or not is analyzed;

a3, detecting the pressure of the motor (5) on the annular plate (11) through a pressure sensor, and judging the shaking degree of the motor (5);

a4, a signal transmission analysis sub-module is used for judging the working efficiency of the winding drum (7).

3. A traceable energy-efficient built-in stage boom assembly according to claim 2, characterized in that: the A3 comprises the following specific operation steps:

a31, when the pressure sensor detects that the pressure of the motor (5) on the annular plate (11) is a constant value, the motor (5) does not shake;

a32, when the pressure sensor detects that the pressure of the motor (5) on the annular plate (11) is larger than a constant value, the motor (5) starts to shake.

4. A traceable energy-efficient built-in stage boom assembly according to claim 3, wherein: the A4 comprises the following specific operation steps:

a41, when rust is not generated between the winding drum (7) and the supporting drum (3) and the motor (5) does not shake, the working efficiency of the winding drum (7) is high;

a42, when the reel (7) and the supporting cylinder (3) do not rust and the motor (5) shakes, or when the reel (7) and the supporting cylinder (3) rust and the motor (5) does not shake, the working efficiency of the reel (7) is intermediate;

a43, when rust is generated between the winding drum (7) and the supporting drum (3), and the motor (5) shakes, the working efficiency of the winding drum (7) is low.

5. A trackable energy-efficient built-in stage boom apparatus according to claim 4, wherein: the maintenance module comprises a blowing sub-module, a temperature sensor and a calculation sub-module, wherein the temperature sensor is respectively positioned inside the supporting cylinder (3) and outside the winding cylinder (7), and the blowing sub-module is positioned on the left inner wall of the winding cylinder (7).

6. A trackable energy-efficient built-in stage boom apparatus according to claim 5, wherein: the maintenance module comprises the following specific operation steps:

s1, detecting the indoor temperature and the temperature of the supporting cylinder (3) through a temperature sensor, transmitting signals to a calculation submodule, judging the temperature difference between the indoor temperature and the supporting cylinder (3), and W _{Support frame} -W _{Outer part} =p, where W _{Support frame} To support the temperature of the surface of the cylinder (3), W _{Outer part} The temperature in the room is P is the temperature difference between the indoor temperature and the supporting cylinder (3), the temperature is in centigrade, when 0<When P is less than or equal to 2, the temperature difference between the indoor and the supporting cylinder (3) at the same time is small, so that the heat exchange speed is low, and the heat dissipation is slow, when P>2, the temperature difference between the indoor and the supporting cylinder (3) at the same time is proved to be large, so that the hot gas exchange speed is high, and the heat dissipation is high;

s2, when the heat dissipation is slow, transmitting a signal to the air blowing sub-module.