WO2024113281A1

WO2024113281A1 - Remote monitoring apparatus based on edge computing

Info

Publication number: WO2024113281A1
Application number: PCT/CN2022/135701
Authority: WO
Inventors: 杜天华; 温怀军; 白梅
Original assignee: 智城六新数字科技研究院(南京)有限公司
Priority date: 2022-11-28
Filing date: 2022-11-30
Publication date: 2024-06-06
Also published as: CN115734585A

Abstract

Disclosed in the present invention is a remote monitoring apparatus based on edge computing, comprising a monitoring terminal and cylindrical filter screens. Openings matched with the cylindrical filter screens are respectively formed in a pair of symmetric side surfaces of the monitoring terminal, and there are two cylindrical filter screens; the two cylindrical filter screens rotate inside the monitoring terminal, and the two sides of the two cylindrical filter screens distant from each other respectively rotate inside the two openings; a first rotating mechanism for driving the two cylindrical filter screens to synchronously rotate is provided inside the monitoring terminal, and a circular recess is formed in the top of the monitoring terminal; fan blades rotate inside the circular recess, and a matched circular filter screen is mounted at the top of the circular recess; a scraper horizontally slides at the top of the circular filter screen, and one end of the bottom of the scraper is fixedly connected to the top center of the fan blades by means of a rotating shaft. According to the present invention, by providing cylindrical filter screens, heat inside a monitoring terminal can be dissipated by means of the cylindrical filter screens, and external dust can be prevented from entering the monitoring terminal.

Description

A remote monitoring device based on edge computing

Technical Field

The present invention relates to the field of remote monitoring technology, and in particular to a remote monitoring device based on edge computing.

Background technique

Edge computing refers to the use of an open platform that integrates network, computing, storage, and application core capabilities to provide the nearest end service on the side close to the object or data source. Its application is initiated on the edge side, resulting in faster network service response, meeting the basic needs of the industry in terms of real-time business, application intelligence, security and privacy protection, etc., while the monitoring terminal is used to collect raw data.

The monitoring terminals of existing edge computing remote monitoring devices usually dissipate heat through heat sinks, and in order to prevent dust from entering the interior of the monitoring terminal, filters are installed on the surface of the heat sinks. However, when in use, the filters are not cleaned, resulting in a large amount of dust adhering to the filters, resulting in poor heat dissipation and reduced efficiency of the monitoring terminal.

Summary of the invention

The purpose of the present invention is to solve the shortcomings existing in the prior art and to propose a remote monitoring device based on edge computing.

In order to achieve the above object, the present invention adopts the following technical solutions:

A remote monitoring device based on edge computing includes a monitoring terminal and a cylindrical filter. The monitoring terminal has symmetrical sides each with an opening that matches the cylindrical filter, and there are two cylindrical filters. Both of the cylindrical filters rotate inside the monitoring terminal, and the two sides of the two cylindrical filters that are far away from each other rotate inside the two openings respectively. A first rotating mechanism is provided inside the monitoring terminal for driving the two cylindrical filters to rotate synchronously, and a circular groove is provided on the top of the monitoring terminal, and a fan blade rotates inside the circular groove. A matching circular filter is installed on the top of the circular groove, and a scraper slides horizontally on the top of the circular filter, and one end of the bottom of the scraper is fixedly connected to the center of the top of the fan blade by a rotating shaft. A second rotating mechanism is provided inside the monitoring terminal for rotating the fan blade, and a heat dissipation mechanism for dissipating heat inside the monitoring terminal is provided inside each cylindrical filter.

Through the setting of this device, not only can the dust adhering to the surface of the filter be cleaned, but the airflow inside the monitoring terminal and the exchange with the outside world can also be accelerated while the filter is being cleaned, thereby improving the heat dissipation effect of the monitoring terminal.

Preferably, the first rotating mechanism includes a first belt and a driving motor, and the first belt rotates horizontally inside the monitoring terminal, first pulleys are provided at both ends of the first belt, and the two first pulleys and the top ends of the two cylindrical filters are connected by a rotating shaft.

As a further technical solution of the present invention, the drive motor is horizontally installed at one end portion inside the monitoring terminal, and the output shaft of the drive motor is installed at the center of the end of one of the cylindrical filters.

Preferably, the heat dissipation mechanism comprises a round roller, and the round roller is horizontally installed at the inner center of the cylindrical filter screen, and a strip plate is horizontally installed on the arc surface of the round roller, and there are multiple strip plates that are evenly distributed in a ring shape.

As a further technical solution of the present invention, the second rotating mechanism includes a second belt and a rotating rod, and the second belt rotates horizontally inside the monitoring terminal, second pulleys are provided at both ends of the second belt, and a round rod is horizontally installed at the center of the end of one of the cylindrical filters, and the other end of the round rod rotates on one side of the monitoring terminal, and one of the second pulleys is sleeved on the surface of the round rod and fixed.

Preferably, the rotating rod is horizontally installed at the center of one side of another second pulley, and a first bevel gear is installed at the other end of the rotating rod, and a second bevel gear is horizontally meshed at the top of the first bevel gear.

As a further technical solution of the present invention, a vertical rod is vertically installed at the bottom center of the second bevel gear, and the end of the vertical rod rotates at the bottom of the monitoring terminal. The same connecting shaft is vertically installed at the top center of the second bevel gear and the center between the fan blades.

Beneficial effects of the present invention:

1. The present invention, through the arrangement of the cylindrical filter, can make the heat inside the monitoring terminal dissipate through the cylindrical filter, and can also prevent external dust from entering the interior of the monitoring terminal. When in use, one of the cylindrical filters is driven to rotate by a driving motor, and the rotation of one of the cylindrical filters will drive the first belt and the first pulley to rotate, and the rotation of the first pulley will drive the other cylindrical filter to rotate, and the rotation of the two cylindrical filters and the contact with the opening will clean the dust adhered to the surface of the cylindrical filter, and the rotation of the two cylindrical filters will drive the two round rollers to rotate, and the rotation of the two round rollers will drive the rotation of multiple strip plates, thereby driving the gas inside the monitoring terminal and the external airflow to flow, accelerating the heat dissipation of the monitoring terminal, and thereby improving the use effect of the device.

2. The present invention can further dissipate heat for the monitoring terminal through the arrangement of fan blades, and can also prevent dust through the circular filter. When the cylindrical filter rotates, it will drive the round rod to rotate, and the rotation of the round rod will drive the second belt and the second pulley to rotate. The rotation of the second pulley will drive the rotating rod to rotate, and the rotation of the rotating rod will drive the first bevel gear to rotate, and the rotation of the first bevel gear will drive the second bevel gear to rotate, and the rotation of the second bevel gear will drive the connecting shaft to rotate, and the rotation of the connecting shaft will drive the fan blades to rotate, so that the monitoring terminal can be dissipated synchronously with the cylindrical filter. In addition, the rotation of the fan blades will also drive the scraper to rotate, and further clean the dust adhered to the surface of the circular filter, thereby improving the heat dissipation effect and use efficiency of the monitoring terminal.

The parts not involved in this device are the same as the existing technology or can be implemented by using the existing technology

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic structural diagram of a remote monitoring device based on edge computing according to the present invention;

FIG2 is a bottom view of a remote monitoring device based on edge computing according to the present invention;

FIG3 is a cross-sectional view of a remote monitoring device based on edge computing according to the present invention;

FIG4 is a cross-sectional view of a cylindrical filter screen of a remote monitoring device based on edge computing according to the present invention.

In the figure: 1. monitoring terminal; 2. cylindrical filter; 3. circular filter; 4. scraper; 5. first belt; 6. first pulley; 7. rotating rod; 8. first bevel gear; 9. second bevel gear; 10. vertical rod; 11. fan blade; 12. second belt; 13. second pulley; 14. round roller; 15. strip plate; 16. connecting shaft; 17. driving motor.

Detailed ways

The technical solutions in the embodiments of the present invention will be described clearly and completely below in conjunction with the drawings in the embodiments of the present invention. Obviously, the described embodiments are only part of the embodiments of the present invention, rather than all the embodiments.

1-4, a remote monitoring device based on edge computing includes a monitoring terminal 1 and a cylindrical filter 2, wherein openings adapted to the cylindrical filter 2 are provided on a symmetrical side of the monitoring terminal 1, and there are two cylindrical filter screens 2, both of which rotate inside the monitoring terminal 1, and the two sides of the two cylindrical filter screens 2 that are far away rotate inside the two openings respectively, a first rotating mechanism for driving the two cylindrical filter screens 2 to rotate synchronously is provided inside the monitoring terminal 1, and a circular groove is provided on the top of the monitoring terminal 1, a fan blade 11 rotates inside the circular groove, a matching circular filter screen 3 is installed on the top of the circular groove, a scraper 4 slides horizontally on the top of the circular filter screen 3, and one end of the bottom of the scraper 4 is fixedly connected to the center of the top of the fan blade 11 through a rotating shaft, a second rotating mechanism for rotating the fan blade 11 is provided inside the monitoring terminal 1, and a heat dissipation mechanism for dissipating heat inside the monitoring terminal 1 is provided inside each cylindrical filter screen 2, through the setting of the device, not only the dust adhering to the surface of the filter screen can be cleaned, but also the airflow inside the monitoring terminal 1 and the exchange with the outside world can be accelerated synchronously when the filter screen is cleaned, thereby improving the heat dissipation effect of the monitoring terminal 1.

1 and 2, in a preferred embodiment, the first rotating mechanism includes a first belt 5 and a driving motor, and the first belt 5 rotates horizontally inside the monitoring terminal 1, first pulleys 6 are provided at both ends of the first belt 5, and the two first pulleys 6 and the top ends of the two cylindrical filter screens 2 are connected by a rotating shaft, the driving motor 17 is horizontally installed at one end of the side inside the monitoring terminal 1, and the output shaft of the driving motor 17 is installed at the center of the end of one of the cylindrical filter screens 2, the heat dissipation mechanism includes a round roller 14, and the round roller 14 is horizontally installed at the center of the inside of the cylindrical filter screen 2, the arc surface of the round roller 14 is horizontally installed with a strip plate 15, and the strip plates 15 are multiple and evenly distributed in a ring shape, through the setting of the first rotating mechanism and the heat dissipation mechanism, it is mainly used to drive the two cylindrical filter screens 2 to rotate, and the strip plates 15 can also be rotated to accelerate the heat dissipation of the monitoring terminal 1 while rotating to remove dust.

4 and 3 , in a preferred embodiment, the second rotating mechanism includes a second belt 12 and a rotating rod 7, and the second belt 12 rotates horizontally inside the monitoring terminal 1, second pulleys 13 are provided at both ends of the second belt 12, and a round rod is horizontally installed at the center of the end of one of the cylindrical filter screens 2, and the other end of the round rod rotates on one side of the monitoring terminal 1, one of the second pulleys 13 is sleeved on the surface of the round rod and fixed, the rotating rod 7 is horizontally installed at the center of one side of the other second pulley 13, and a first bevel gear 8 is installed at the other end of the rotating rod 7, a second bevel gear 9 is horizontally meshed with the top of the first bevel gear 8, a vertical rod 10 is vertically installed at the center of the bottom of the second bevel gear 9, and the end of the vertical rod 10 rotates at the bottom of the monitoring terminal 1, and the same connecting shaft 16 is vertically installed at the center of the top of the second bevel gear 9 and the center between the fan blades 11. Through the setting of the second rotating mechanism, it is mainly used for the cylindrical filter screen 2 and the fan blades 11 to rotate synchronously, so that the monitoring terminal 1 can be dissipated synchronously, thereby improving the heat dissipation effect of the monitoring terminal 1.

Working principle: when in use, one of the cylindrical filters 2 is driven to rotate by the driving motor 17, and the rotation of one of the cylindrical filters 2 will drive the first belt 5 and the first pulley 6 to rotate, and the rotation of the first pulley 6 will drive the other cylindrical filter 2 to rotate, and the two cylindrical filters 2 will rotate and contact with the opening to clean the dust adhering to the surface of the cylindrical filter 2, and the rotation of the two cylindrical filters 2 will drive the two round rollers 14 to rotate, and the rotation of the two round rollers 14 will drive the rotation of multiple strip plates 15, thereby driving the gas inside the monitoring terminal 1 and the air flow outside, accelerating the heat dissipation of the monitoring terminal 1, and thereby improving the use effect of the device, when the cylindrical filter 2 rotates, it will drive the round rod to rotate, and the rotation of the round rod will drive the second belt 12 and The second pulley 13 rotates, and the rotation of the second pulley 13 drives the rotating rod 7 to rotate. The rotation of the rotating rod 7 drives the first bevel gear 8 to rotate. The rotation of the first bevel gear 8 drives the second bevel gear 9 to rotate. The rotation of the second bevel gear 9 drives the connecting shaft 16 to rotate. The rotation of the connecting shaft 16 drives the fan blades 11 to rotate, so that it can rotate synchronously with the cylindrical filter 2 to dissipate heat for the monitoring terminal 1. In addition, the rotation of the fan blades 11 also drives the scraper 4 to rotate, and further cleans the dust adhered to the surface of the circular filter 3.

The basic principles and main features of the present invention and the advantages of the present invention are shown and described above. For those skilled in the art, it is obvious that the present invention is not limited to the details of the above exemplary embodiments, and the present invention can be implemented in other specific forms without departing from the spirit or basic features of the present invention. Therefore, no matter from which point of view, the embodiments should be regarded as exemplary and non-restrictive. The scope of the present invention is limited by the attached claims rather than the above description. Therefore, it is intended to include all changes within the meaning and scope of the equivalent elements of the claims in the present invention, and any figure marks in the claims should not be regarded as limiting the claims involved.

In addition, it should be understood that although the present specification is described according to implementation modes, not every implementation mode contains only one independent technical solution. This description of the specification is only for the sake of clarity. Those skilled in the art should regard the specification as a whole. The technical solutions in each embodiment may also be appropriately combined to form other implementation modes that can be understood by those skilled in the art.

Claims

A remote monitoring device based on edge computing, comprising a monitoring terminal (1) and a cylindrical filter (2), characterized in that an opening adapted to the cylindrical filter (2) is provided on a symmetrical side of the monitoring terminal (1), and there are two cylindrical filters (2), both of which rotate inside the monitoring terminal (1), and the two sides of the two cylindrical filters (2) that are far from each other rotate inside the two openings respectively, and a first rotating device is provided inside the monitoring terminal (1) for driving the two cylindrical filters (2) to rotate synchronously The monitoring terminal (1) has a circular groove on the top, a fan blade (11) rotates inside the circular groove, a matching circular filter (3) is installed on the top of the circular groove, a scraper (4) slides horizontally on the top of the circular filter (3), and one end of the bottom of the scraper (4) is fixedly connected to the center of the top of the fan blade (11) through a rotating shaft, a second rotating mechanism for rotating the fan blade (11) is provided inside the monitoring terminal (1), and a heat dissipation mechanism for dissipating heat inside the monitoring terminal (1) is provided inside each cylindrical filter (2).
According to a remote monitoring device based on edge computing as described in claim 1, it is characterized in that the first rotating mechanism includes a first belt (5) and a driving motor, and the first belt (5) rotates horizontally inside the monitoring terminal (1), and first pulleys (6) are provided at both ends of the first belt (5), and the two first pulleys (6) and the top ends of the two cylindrical filters (2) are connected by a rotating shaft.
According to a remote monitoring device based on edge computing as described in claim 2, it is characterized in that the drive motor (17) is horizontally installed at an end portion of one side inside the monitoring terminal (1), and the output shaft of the drive motor (17) is installed at the center of the end of one of the cylindrical filters (2).
According to a remote monitoring device based on edge computing as described in claim 3, it is characterized in that the heat dissipation mechanism includes a round roller (14), and the round roller (14) is horizontally installed at the center of the cylindrical filter (2), and the arc surface of the round roller (14) is horizontally installed with a strip plate (15), and there are multiple strip plates (15) that are evenly distributed in a ring shape.
According to a remote monitoring device based on edge computing as described in claim 4, it is characterized in that the second rotating mechanism includes a second belt (12) and a rotating rod (7), and the second belt (12) rotates horizontally inside the monitoring terminal (1), and second pulleys (13) are provided at both ends of the second belt (12), and a round rod is horizontally installed at the center of the end of one of the cylindrical filters (2), and the other end of the round rod rotates on one side of the monitoring terminal (1), and one of the second pulleys (13) is sleeved on the surface of the round rod and fixed.
According to a remote monitoring device based on edge computing as described in claim 5, it is characterized in that the rotating rod (7) is horizontally installed at the center of one side of another second pulley (13), and a first bevel gear (8) is installed at the other end of the rotating rod (7), and a second bevel gear (9) is horizontally meshed at the top of the first bevel gear (8).
According to a remote monitoring device based on edge computing as described in claim 6, it is characterized in that a vertical rod (10) is vertically installed at the bottom center of the second bevel gear (9), and the end of the vertical rod (10) rotates at the bottom of the monitoring terminal (1), and the same connecting shaft (16) is vertically installed at the top center of the second bevel gear (9) and the center between the fan blades (11).