CN117098350A - Turnover-based detection device and method for electric automation equipment - Google Patents

Abstract

The invention relates to the technical field of detection of electric automation equipment, in particular to a turnover-based detection device and a turnover-based detection method of the electric automation equipment. The electric automation device comprises a fixed functional body and a movable functional body which are arranged on the electric automation device, wherein a sensing group is arranged in the electric automation device, the fixed functional body comprises a signal transmitter body and a fixed seat arranged on the back side of the signal transmitter body, and the top of the signal transmitter body is rotationally connected with the fixed seat. When the movable functional body moves upwards along the guide plates, the movable functional body pushes the clans to the space between the two guide plates so as to push the signal transmitter body to turn over, the external connection end faces the acquisition part in the turning process, and meanwhile, the acquisition part is close to the external connection end and is connected with the acquisition part, so that the length required by connection of the acquisition part can be shortened, the detection cost is reduced, and the problem that the lines used by the acquisition part are difficult to arrange is solved.

Description

Turnover-based detection device and method for electric automation equipment

Technical Field

The invention relates to the technical field of detection of electric automation equipment, in particular to a turnover-based detection device and a turnover-based detection method of the electric automation equipment.

Background

The electric automation equipment detection device consists of a sensor, a signal transmitter, a data acquisition card, a computer and other equipment.

The sensor is a device for sensing and transforming physical quantity, is usually used for collecting various signals such as measured electrical signals, mechanical signals and the like, and common sensor types include displacement sensors, pressure sensors, temperature sensors, vibration sensors and the like; the signal transmitter converts the signal collected by the sensor into a standard signal (such as a current signal or a voltage signal) and outputs the standard signal to the data acquisition card for acquisition and storage; the data acquisition card is used for converting the standard signal into a digital signal and transmitting the digital signal to a computer for data processing and analysis; the computer is the main equipment for data analysis, diagnosis, early warning and fault removal, and processes and analyzes the related information of equipment operation to judge whether the equipment is in a normal state or whether the equipment has problems of faults, potential risks and the like.

Through the cooperative action of the equipment, the electric automation equipment detection device can realize the functions of collecting, analyzing and diagnosing the running state of the equipment.

In the actual detection process, the engineer who is responsible for detection is often required to connect the equipment (namely the acquisition card) for acquiring data with the signal transmitter through the corresponding transmission line so as to acquire the data in the equipment, then the data is transmitted to the computer, analysis and processing are carried out through the computer, and in the process, the computer also needs to find a place to place the acquisition card, or the acquisition card is taken on the hand of the engineer, no matter the acquisition card is far away from the signal transmitter, so that a longer transmission line is required to be arranged, namely the detection cost is increased, and the transmission line is inconvenient to arrange.

Disclosure of Invention

The invention aims to provide a turnover-based detection device and a turnover-based detection method for electric automation equipment, so as to solve the problems in the background technology.

In order to achieve the above object, one of the purposes of the present invention is to provide a turnover-based detection device for an electric automation device, which comprises a fixed functional body and a movable functional body, wherein the fixed functional body is installed on the electric automation device, the fixed functional body is exposed outside, a sensing group is arranged in the electric automation device, the sensing group is used for measuring signals in the electric automation device through a sensor, the fixed functional body comprises a signal transmitter body, the signal transmitter body is used for converting signals collected by the sensing group into standard signals, an external connection end is arranged at the bottom of the signal transmitter body, the fixed functional body also comprises a fixed seat arranged at the back side of the signal transmitter body, and the top of the signal transmitter body is rotationally connected with the fixed seat;

two guide plates are symmetrically arranged at the bottom of the fixed seat;

during detection, the movable functional body moves along the guide plate;

the movable functional body is provided with a pushing part and a collecting part;

the pushing part is located in the space between the two guide plates to push the signal transmitter body to overturn, the external connection end faces the collecting part in the overturning process, and meanwhile, the collecting part is close to the external connection end;

the acquisition part after the approach is connected with the external connection end.

As a further improvement of the technical scheme, the conveying end of the acquisition part is connected with an acquisition card and is used for conveying the received standard signal to the acquisition card; and after the standard signal is converted into a digital signal by the acquisition card, the digital signal is transmitted to a computer for analysis and processing so as to detect the electric automation equipment.

As a further improvement of the technical scheme, the top of the signal transmitter body is provided with an internal connection end which is used for being connected with a sensor inside the electric automation equipment.

As a further improvement of the technical scheme, the bottom of the back side of the signal transmitter body is provided with a biting plate, and the movable functional body is stopped on the guide plate through the biting plate and the pushing part in a biting mode.

As a further improvement of the technical scheme, a rotary groove is formed in the back side of the top of the signal transmitter body, a switching part is arranged on the fixing seat, a rotating shaft is arranged in the rotary groove, and the switching part is rotationally connected with the rotating shaft;

the two sides of the switching part are provided with reserved spaces so as to provide space for overturning the signal transmitter body.

As a further improvement of the technical scheme, the pushing part comprises a pushing seat and sliding parts, wherein the sliding parts are arranged at two sides of the pushing seat respectively;

the sliding connection part is provided with a sliding groove which is in sliding connection with the guide plate;

the pushing seat is of a wedge-shaped structure so as to form a wedge-shaped surface;

the top end of the wedge-shaped surface falls into the space between the two guide plates;

the sliding connection part is connected with a detection frame, the opposite side of the wedge-shaped surface of the pushing seat is connected with a detection panel, and a collection card and a computer are mounted in the detection panel;

the detection frame forms a containing space between the detection panel and the pushing seat, and the bottom of the detection panel is provided with a collection end;

in the overturning process, the signal transmitter body is accommodated in the accommodating space by attaching the wedge-shaped surface, and is close to the acquisition end, and the acquisition part is formed by the acquisition end and is connected with the external end;

the width of the pushing seat is equal to or smaller than the distance between the two guide plates.

As a further improvement of the technical scheme, a backboard is arranged at the bottom of the fixing seat and positioned between the two guide plates, the backboard is in an L-shaped arrangement, and a board body at the bottom of the L-shaped backboard is used for protecting an external connection end positioned at the bottom;

the arrangement of the external connection terminals falls into the coverage area of the backboard;

the pushing seat is provided with an empty groove, and the empty groove provides space for the pushing seat to pass through the backboard;

the bottom of the pushing seat forms a biting part, and the biting part and the biting plate are mutually meshed after the pushing seat is in place.

As a further improvement of the technical scheme, the width of the back plate is equal to or narrower than the width of the pushing seat;

the width of the biting plate is equal to or narrower than the width of the empty slot.

As a further improvement of the technical scheme, a flexible constraint part is arranged on the plate body at the bottom of the back plate and is used for filling the space at the bottom of the external terminal;

and a gap is formed between the flexible restraining parts and is used for restraining a circuit detached from the signal transmitter body.

It is a second object of the present invention to provide a method for using a roll-over based electrical automation device detection apparatus comprising the following method steps:

step one, moving a movable functional body upwards along a guide plate;

step two, pushing the clan to a space between the two guide plates in the movement process so as to push the signal transmitter body to overturn, enabling the external connection end to face the acquisition part in the overturning process, and enabling the acquisition part to be close to the external connection end;

and thirdly, after the distance between the acquisition part and the external connection end is shortened in a close mode, the acquisition part is connected with the external connection end.

Compared with the prior art, the invention has the beneficial effects that:

1. in this electric automation equipment detection device and method based on upset, when the movable functional body upwards moved along the baffle, promote the space that the tribe was in between two baffles to promote the signal transmitter body and overturn, the in-process that overturns makes external end towards collection portion, simultaneously, collection portion is close to external end to establish the connection with it, can shorten collection portion length that needs of connection like this, thereby reduced detection cost, also solved the problem that is difficult to carry out the arrangement to the circuit that collection portion used.

2. According to the turnover-based electric automation equipment detection device and method, the movable functional body is kept on the guide plate through the engagement of the engagement plate and the pushing part, so that when the detection is performed, engineers are more responsible for observation and recording, the problems in connection and equipment placement are not considered, and the work load and the operation difficulty of the engineers are reduced.

3. In this electric automation equipment detection device and method based on convertible, flexible restraint portion comprises a plurality of sponge pieces or a plurality of brush hair, fills the space of outer terminal bottom on the one hand, avoids the dust to enter into in the outer terminal, and on the other hand is restraint the circuit of dismantling in the signal transmitter body through the clearance between sponge piece or the brush hair to the going on of maintenance operation of being convenient for.

Drawings

FIG. 1 is a schematic view of the motion direction of a movable functional body according to the present invention;

FIG. 2 is a schematic view of the structure of the fixing function body of the present invention;

FIG. 3 is a schematic view of the structure of the guide plate and the back plate of the present invention;

FIG. 4 is a schematic diagram of the structure of the movable functional body of the present invention;

FIG. 5 is a schematic view of the back plate and propulsion seat structure of the present invention;

FIG. 6 is a schematic diagram of a propulsion seat and signal transmitter configuration of the present invention;

FIG. 7 is a schematic side view of the fixed and movable functional bodies of the present invention;

fig. 8 is a schematic view of the flexible restraint structure of the present invention.

The meaning of each reference sign in the figure is:

100. fixing the functional body; 200. a movable functional body;

110. a signal transmitter body; 111. an external connection end; 112. a bite plate; 113. an inner joint end; 110A, a rotating groove;

120. a fixing seat; 121. a guide plate; 122. a back plate; 1221. a flexible constraining section; 123. a switching part;

210. a propulsion seat; 210A, empty slots; 211. a slip joint part; 211A, a chute; 212. a bite portion; 220. a detection frame; 220A, an accommodating space; 221. a detection panel; 222. and a collection end.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present invention, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

The electric automation equipment detection device consists of a sensor, a signal transmitter, a data acquisition card, a computer and other equipment.

The sensor is a device for sensing and transforming physical quantity, is usually used for collecting various signals such as measured electrical signals, mechanical signals and the like, and common sensor types include displacement sensors, pressure sensors, temperature sensors, vibration sensors and the like; the signal transmitter converts the signal collected by the sensor into a standard signal (such as a current signal or a voltage signal) and outputs the standard signal to the data acquisition card for acquisition and storage; the data acquisition card is used for converting the standard signal into a digital signal and transmitting the digital signal to a computer for data processing and analysis; the computer is the main equipment for data analysis, diagnosis, early warning and fault removal, and processes and analyzes the related information of equipment operation to judge whether the equipment is in a normal state or whether the equipment has problems of faults, potential risks and the like.

To this end, the embodiment provides a turnover-based detection device for an electric automation device, as shown in fig. 1, which includes a fixed functional body 100 and a movable functional body 200, the fixed functional body 100 is mounted on the electric automation device, the fixed functional body 100 is exposed (the exposed part refers to a state where the fixed functional body 100 is not contacted to the fixed functional body by a disassembling mode, and the fixed functional body 100 can be in a closed state by closing a cabinet door), a sensing group is disposed in the electric automation device, the sensing group measures various signals such as an electric signal, a mechanical signal and the like in the electric automation device through various types of sensors, and referring to fig. 2, the fixed functional body 100 includes a signal transmitter body 110, the signal transmitter body 110 is used for converting the signal collected by the sensing group into a standard signal (for example, a current signal or a voltage signal), and an external terminal 111 is disposed at the bottom of the signal transmitter body 110.

With continued reference to fig. 2, the fixing functional body 100 further includes a fixing seat 120 disposed on the back side of the signal transmitter body 110, the top of the signal transmitter body 110 is rotationally connected with the fixing seat 120, and two guide plates 121 are symmetrically disposed at the bottom of the fixing seat 120; at the time of detection, the movable functional body 200 moves along the guide plate 121, wherein:

the movable functional body 200 is provided with a pushing part and a collecting part, when the movable functional body 200 moves upwards along the guide plates 121, the pushing part is located in a space between the two guide plates 121 to push the signal transmitter body 110 to turn over, the external connection end 111 faces the collecting part in the turning process, and meanwhile, the collecting part is close to the external connection end 111 and is connected with the external connection end 111, so that the length required by connection of the collecting part can be shortened, the detection cost is reduced, and the problem that a circuit used by the collecting part is difficult to arrange is solved;

the bottom of the back side of the signal transmitter body 110 is provided with the biting plate 112, and the movable functional body 200 is stopped on the guide plate 121 by biting the biting plate 112 and the pushing part, so that during detection, engineers are more responsible for observation and recording, and the problems of connection and equipment placement are not considered, thereby reducing the workload and the operation difficulty of the engineers;

the conveying end of the acquisition part is connected with an acquisition card and is used for conveying the received standard signals to the acquisition card, and after the standard signals are converted into digital signals through the acquisition card, the acquisition card conveys the digital signals to a computer for analysis and processing so as to detect the electric automation equipment.

In fig. 2, an inner connection end 113 is provided at the top of the signal transmitter body 110, the inner connection end 113 is used for being connected with a sensor inside an electric automation device, a rotating groove 110A is provided at the back side of the top of the signal transmitter body 110, as shown in fig. 3, a switching part 123 is provided on the fixing base 120, a rotating shaft is provided in the rotating groove 110A, the switching part 123 is rotationally connected with the rotating shaft, and reserved spaces are provided at two sides of the switching part 123 to ensure that the signal transmitter body 110 can be smoothly turned over, and screws are also provided in the reserved spaces to fix the fixing base 120 on the electric automation device.

Referring to fig. 4, the pushing portion includes a pushing seat 210 and two sliding portions 211, the sliding portions 211 are respectively located at two sides of the pushing seat 210, the sliding portions 211 are provided with sliding grooves 211A, the sliding grooves 211A are sleeved on the guide plates 121 and then slide on the guide plates 121, the pushing seat 210 is in a wedge structure, and the top end forming a wedge surface falls in a space between the two guide plates 121, so that the wedge surface can enter the back side of the signal transmitter body 110 and contact the signal transmitter body 110 in the process of moving up the pushing seat 210, and the signal transmitter body 110 is pushed to turn over by the wedge surface.

The sliding connection part 211 is connected with a detection frame 220, a detection panel 221 is connected to the opposite side of the wedge surface of the pushing seat 210 through the detection frame 220, a collection card and a computer are mounted in the detection panel 221, a display screen is arranged outside the detection panel 221 so as to display the detection result obtained by analysis and processing of the computer for an engineer to record and observe, a containing space 220A is formed between the detection panel 221 and the pushing seat 210 through the detection frame 220, a collection end 222 is arranged at the bottom of the detection panel 221, the signal transmitter body 110 in the overturning process is attached to the wedge surface and is contained in the containing space 220A, meanwhile, the collection end 222 is close to the collection end, the collection part and the external connection end 111 are formed through the collection end 222, and the connection mode can be contact type (for example, signal transmission is realized through patch contact), or plug-in type communication, and the length of a line is effectively overlapped.

It should be noted that the width of the pushing seat 210 is equal to or smaller than the distance between the two guide plates 121.

Further, as shown in fig. 2 and 3, the bottom of the fixing base 120 is disposed between two guide plates 121, the back plate 122 is disposed in an L shape, the plate body at the bottom of the back plate 122 is used for protecting the external connection end 111 at the bottom, for this purpose, the external connection end 111 needs to be arranged within the coverage area of the back plate 122, and in order to enable the pushing base 210 to move smoothly on the guide plates 121, as shown in fig. 5, a hollow groove 210A is further required to be formed on the pushing base 210, the hollow groove 210A provides space for the pushing base 210 to pass through the back plate 122, and a meshing portion 212 is formed at the bottom of the pushing base 210, and the meshing portion 212 and the meshing plate 112 mesh with each other after the pushing base 210 is in place, where the pushing base 210 moves upwards to the maximum extent.

Moreover, the width of the back plate 122 is equal to or smaller than the width of the pushing seat 210, so that after the empty slot 210A is formed, the pushing seat 210 also has a wedge surface for pushing the signal transmitter body 110 to turn over.

Also, as shown in fig. 6 and 7, the width a of the bite plate 112 is equal to or narrower than the width of the recess 210A, so that the mutual abrasion between the bite plate 112 and the inclined surface is reduced as much as possible, and in order to further reduce the abrasion therebetween, the cross section of the bite 212 is also arranged in a triangle shape with the apex angle between 110 ° and 150 °, thereby reducing the distance that the wedge-shaped surface contacts the bite plate 112.

In addition, the space of the hollow groove 210A is further enlarged, so that the back plate of the signal transmitter body 110 can be detached through the hollow groove 210A, thereby facilitating the overhaul of the internal parts.

Still further, as shown in fig. 8, a flexible restraining portion 1221 is disposed on a plate body at the bottom of the back plate 122, the flexible restraining portion 1221 is composed of a plurality of sponge blocks or a plurality of bristles, on one hand, space at the bottom of the external connection end 111 is filled to avoid dust entering into the external connection end 111, and on the other hand, lines detached from the signal transmitter body 110 are restrained through gaps between the sponge blocks or the bristles, so as to facilitate maintenance operation.

The embodiment also provides a method for using the turnover-based detection device of the electric automation equipment, which comprises the following method steps:

step one, the movable functional body 200 moves upwards along the guide plate 121;

step two, pushing the clan to the space between the two guide plates 121 in the movement process so as to push the signal transmitter body 110 to overturn, and enabling the external connection end 111 to face the acquisition part in the overturning process, wherein the acquisition part is close to the external connection end 111;

step three, after shortening the distance between the collecting part and the external connection terminal 111 in a close manner, the collecting part is connected with the external connection terminal 111.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present invention, and are not intended to limit the invention, and that various changes and modifications may be made therein without departing from the spirit and scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. Based on convertible electric automation equipment detection device, it includes fixed function body (100) and movable function body (200) of installing on electric automation equipment, fixed function body (100) are exposed outside, be provided with the sensing group in the electric automation equipment, the sensing group is used for measuring the signal in the electric automation equipment through the sensor, fixed function body (100) include signal transmitter body (110), signal transmitter body (110) are used for converting the signal that the sensing group gathered into standard signal, signal transmitter body (110) bottom is provided with external end (111), its characterized in that: the fixed function body (100) further comprises a fixed seat (120) arranged on the back side of the signal transmitter body (110), and the top of the signal transmitter body (110) is rotationally connected with the fixed seat (120);

two guide plates (121) are symmetrically arranged at the bottom of the fixed seat (120);

during detection, the movable functional body (200) moves along the guide plate (121);

the movable functional body (200) is provided with a pushing part and a collecting part;

the pushing part is located in a space between the two guide plates (121) to push the signal transmitter body (110) to overturn, the external connection end (111) faces the collecting part in the overturning process, and meanwhile, the collecting part is close to the external connection end (111);

the acquisition part after the approach is connected with an external connection end (111).

2. The roll-over-based electrical automation device testing apparatus of claim 1, wherein: the conveying end of the acquisition part is connected with an acquisition card and is used for conveying the received standard signals to the acquisition card; and after the standard signal is converted into a digital signal by the acquisition card, the digital signal is transmitted to a computer for analysis and processing so as to detect the electric automation equipment.

3. The roll-over-based electrical automation device testing apparatus of claim 1, wherein: the top of the signal transmitter body (110) is provided with an internal connection end (113), and the internal connection end (113) is used for being connected with a sensor inside the electric automation equipment.

4. A roll-over-based electrical automation device testing apparatus in accordance with any one of claims 1 to 3 wherein: the bottom of the back side of the signal transmitter body (110) is provided with a biting plate (112), and the movable functional body (200) is stopped on the guide plate (121) through the biting plate (112) and the pushing part.

5. A roll-over-based electrical automation device testing apparatus in accordance with claims 1-3 wherein: a rotary groove (110A) is formed in the back side of the top of the signal transmitter body (110), a switching part (123) is arranged on the fixing seat (120), a rotating shaft is arranged in the rotary groove (110A), and the switching part (123) is rotationally connected with the rotating shaft;

the two sides of the switching part (123) are provided with reserved spaces so as to provide space for overturning the signal transmitter body (110).

6. The roll-over-based electrical automation device testing apparatus of claim 4, wherein: the pushing part comprises a pushing seat (210) and sliding parts (211), wherein the sliding parts (211) are arranged at two sides of the pushing seat (210) respectively;

the sliding connection part (211) is provided with a sliding groove (211A), and the sliding groove (211A) is in sliding connection with the guide plate (121);

the propulsion seat (210) is of a wedge-shaped structure so as to form a wedge-shaped surface;

the top end of the wedge-shaped surface falls into the space between the two guide plates (121);

the sliding connection part (211) is connected with a detection frame (220), the opposite side of the wedge-shaped surface of the pushing seat (210) is connected with a detection panel (221) by the detection frame (220), and a collection card and a computer are mounted in the detection panel (221);

the detection frame (220) forms a containing space (220A) between the detection panel (221) and the pushing seat (210), and a collection end (222) is arranged at the bottom of the detection panel (221);

in the overturning process, the signal transmitter body (110) is accommodated in the accommodating space (220A) by attaching the wedge-shaped surface, and is close to the acquisition end (222), and the acquisition part and the external connection end (111) are formed through the acquisition end (222) to establish connection;

the width of the pushing seat (210) is equal to or smaller than the distance between the two guide plates (121).

7. The roll-over-based electrical automation device testing apparatus of claim 6, wherein: a back plate (122) is arranged at the bottom of the fixing seat (120) and positioned between the two guide plates (121), the back plate (122) is in an L-shaped arrangement, and a plate body at the bottom of the L-shaped back plate (122) is used for protecting an external end (111) positioned at the bottom;

the arrangement of the external connection ends (111) falls into the coverage range of the backboard (122);

an empty groove (210A) is formed in the pushing seat (210), and the empty groove (210A) provides space for the pushing seat (210) to pass through the backboard (122);

the bottom of the pushing seat (210) forms a meshing part (212), and the meshing part (212) and the meshing plate (112) are meshed with each other after the pushing seat (210) is in place.

8. The roll-over-based electrical automation device testing apparatus of claim 7, wherein: the width of the backboard (122) is equal to or narrower than the width of the pushing seat (210);

the width of the bite plate (112) is equal to or narrower than the width of the empty slot (210A).

9. The roll-over-based electrical automation device testing apparatus of claim 8, wherein: a flexible constraint part (1221) is arranged on the plate body at the bottom of the back plate (122), and the flexible constraint part (1221) is used for filling the space at the bottom of the external connection end (111);

and a gap is formed between the flexible restraining parts (1221) and is used for restraining a line detached from the signal transmitter body (110).

10. Method for using a roll-over type electric automation device detection apparatus according to any of the claims 6-9, characterized in that it comprises the following method steps:

step one, the movable functional body (200) moves upwards along the guide plate (121);

step two, pushing the clan to be positioned in a space between the two guide plates (121) in the movement process so as to push the signal transmitter body (110) to overturn, enabling the external connection end (111) to face the acquisition part in the overturning process, and enabling the acquisition part to be close to the external connection end (111);

and thirdly, after the distance between the acquisition part and the external connection end (111) is shortened in a close manner, the acquisition part is connected with the external connection end (111).