CN115014549A

CN115014549A - Wireless monitoring system of sliding connection type bus duct based on hybrid networking

Info

Publication number: CN115014549A
Application number: CN202210749079.2A
Authority: CN
Inventors: 曹云峰; 孔红顺; 万超建
Original assignee: Zhenjiang Yituo Electric Co ltd
Current assignee: Zhenjiang Yituo Electric Co ltd
Priority date: 2022-06-29
Filing date: 2022-06-29
Publication date: 2022-09-06
Anticipated expiration: 2042-06-29

Abstract

The invention relates to the field of bus duct equipment, and discloses a wireless monitoring system of a sliding connection type bus duct based on a mixed networking, which effectively solves the problems that the monitoring data is single and result errors are easy to cause when the temperature of the current bus is monitored, and comprises a bus duct body, wherein groove bodies are equidistantly arranged in the bus duct body, bus duct bodies are arranged in the groove bodies, monitoring assemblies are arranged at the bottom end of the bus duct body, mounting assemblies are arranged at the bottom end of the bus duct body, and each monitoring assembly comprises a monitoring groove which is equidistantly arranged at the bottom end of the groove body. The monitoring accuracy of the temperature of each bus body is improved, and therefore the monitoring effect is improved.

Description

Wireless monitoring system of sliding connection type bus duct based on hybrid networking

Technical Field

The invention belongs to the field of bus duct equipment, and particularly relates to a wireless monitoring system of a sliding connection type bus duct based on hybrid networking.

Background

The bus duct is a device for large current transmission, and in the bus use, because inside current is great, thereby it is serious to make the bus easily generate heat, thereby need carry out temperature monitoring to the bus, avoid the bus high temperature and damage, and when carrying out temperature monitoring to the bus, generally laminate temperature sensor's monitor probe and bus surface somewhere, thereby detect the bus temperature through temperature sensor, but still have a defect:

in the working process of the bus, the temperatures at different positions may be different, and only the temperature at a certain position of the bus is monitored, so that an error is easily generated in a monitoring result.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the invention provides a hybrid networking-based wireless monitoring system for a slip bus duct, which effectively solves the problems that the monitoring data is single and result errors are easily caused when the temperature of the conventional bus is monitored.

In order to achieve the purpose, the invention provides the following technical scheme: a wireless monitoring system of a sliding connection type bus duct based on a hybrid networking comprises a bus duct body, wherein groove bodies are equidistantly arranged in the bus duct body, a bus body is arranged in each groove body, a monitoring assembly is arranged at the bottom end of the bus duct body, and an installation assembly is arranged at the bottom end of the bus duct body;

the monitoring assembly comprises monitoring grooves which are equidistantly formed in the bottom end of the groove body, the bottom end of the bus duct body is provided with a mounting frame, mounting grooves are uniformly formed in the mounting frame, the mounting grooves are matched with the monitoring grooves, and circuit detection units are mounted in the mounting grooves;

the circuit detection unit comprises a movable block arranged in the mounting groove, and a temperature monitoring unit is arranged in the movable block;

the temperature monitoring unit is including offering in the inside groove of movable block, and the top groove has been seted up on the top of inside groove, and the inside grafting of top groove has the connecting rod, and inside heat conduction piece is installed to the bottom of connecting rod, and inside heat conduction piece is located the inside of inside groove, and outside heat conduction piece is installed on the top of connecting rod, and first spring is installed to the bottom of outside heat conduction piece, the bottom of first spring and the top fixed connection of movable block, and the internally mounted of movable block has monitor, and monitor's one end electric connection has temperature sensor.

Preferably, first slider is installed to the front and the back symmetry of movable block, and first slider sliding connection is in the inside of first spout, and the front and the back of mounting groove are seted up to first spout symmetry, and exhaust unit is installed to the bottom of movable block.

Preferably, the insulating blocks are symmetrically arranged on two sides of the movable block, the conducting rods are arranged inside the insulating blocks, the two ends of each conducting rod are respectively arranged at the top ends of the two insulating blocks, and the conducting rods are electrically connected with the detection lamps.

Preferably, the exhaust unit is including seting up the bottom groove in the movable block bottom, and the internally mounted in bottom groove is pegged graft and is had the piston piece, and the outer wall of piston piece is hugged closely with the inside in bottom groove, and the second spout has been seted up to the front and the back symmetry in bottom groove, and the inside sliding connection of second spout has the second slider, and the second slider symmetry is installed in the front and the back of piston piece.

Preferably, the inside symmetry of piston block has seted up the air discharge duct, and the air discharge duct setting is the L type, and the top of air discharge duct runs through to the top of piston block, and the other end of air discharge duct runs through to the lateral wall of piston block on, and monitor installs in the top of piston block, and temperature sensor installs in the bottom of piston block.

Preferably, the inner wall of the bottom groove is symmetrically provided with clamping grooves, the two sides of the piston block are symmetrically provided with movable grooves, the movable grooves are movably mounted inside the clamping blocks, the clamping blocks are inserted into the clamping grooves, the ends, close to each other, of the two clamping blocks are provided with second springs, and one ends of the second springs are fixedly connected with the inner walls of the clamping blocks.

Preferably, the bottom in movable groove has seted up the intercommunication groove, and the guide way has been seted up to the bottom in intercommunication groove, and the guide way runs through to the bottom of piston piece, and the inside grafting of guide way has the guide bar, and the top of guide bar is rotated and is connected with the bull stick, and the top and the movable groove of bull stick rotate to be connected, install the connecting rod between two, and the connecting rod is located the below of piston piece.

Preferably, the installation component is including installing in the inserted bar of bus duct body bottom four corners department, and the thread groove has been seted up to the bottom of inserted bar, and the inside threaded connection of thread groove has the screw rod, and the joint piece is installed to the bilateral symmetry of screw rod.

Preferably, the monitoring groove is uniformly provided with slots, the slots are matched with the inserted rods, the two sides of the slots are symmetrically provided with clamping grooves, and the clamping grooves are matched with the clamping blocks.

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

(1) according to the invention, the temperature of the bus body is transmitted to the inside of the inner groove through the connecting rod and the inner heat conducting block through the outer heat conducting block, the monitoring probe transmits the temperature to the temperature sensors, the temperature of the bus body is conveniently monitored, and meanwhile, the plurality of temperature sensors are arranged at the bottom end of each bus body, so that the monitoring accuracy of the temperature of each bus body is improved, and the monitoring effect is improved;

(2) according to the bus body, after the movable block is pushed to move, two ends of the conducting rod are in contact with the bus body, so that the bus body, the conducting rod and the detection lamps form a loop, and then the short-circuit position of the bus body is detected according to the on-off condition of each detection lamp, so that the bus body is convenient to overhaul;

(3) according to the bus bar, the guide rod is pulled downwards, so that the clamping block is separated from the clamping groove in a clamping mode, then the piston block moves downwards, the bottom end of the exhaust groove is separated from the bottom groove, the inside of the movable block is communicated with the outside, the movable block can move conveniently, and the bus bar body can be detected conveniently.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

In the drawings:

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of a monitoring tank according to the present invention;

FIG. 3 is a schematic view of the mounting assembly of the present invention;

FIG. 4 is a schematic view of the structure of the mounting bracket of the present invention;

FIG. 5 is a schematic view of the mounting groove structure of the present invention;

FIG. 6 is a schematic diagram of a circuit detecting unit according to the present invention;

FIG. 7 is a schematic structural diagram of a temperature monitoring unit according to the present invention;

FIG. 8 is a schematic view of the exhaust unit of the present invention;

FIG. 9 is a schematic view of the internal structure of the piston block of the present invention;

in the figure: 1. a bus duct body; 2. a trough body; 3. a bus body; 4. a monitoring component; 401. monitoring the tank; 402. a mounting frame; 403. mounting grooves; 404. a circuit detection unit; 4041. a movable block; 4042. a first chute; 4043. a first slider; 4044. an insulating block; 4045. a conductive rod; 4046. detecting a light; 405. a temperature monitoring unit; 4051. an inner tank; 4052. a top groove; 4053. an internal heat conducting block; 4054. a connecting rod; 4055. an external heat conducting block; 4056. a first spring; 4057. monitoring the probe; 4058. a temperature sensor; 406. an exhaust unit; 4061. a bottom groove; 4062. a piston block; 4063. a second chute; 4064. a second slider; 4065. an exhaust groove; 4066. a card slot; 4067. a movable groove; 4068. a clamping block; 4069. a second spring; 40610. a communicating groove; 40611. a guide groove; 40612. a rotating rod; 40613. a guide bar; 40614. a connecting rod; 5. mounting the component; 501. inserting a rod; 502. a screw groove; 503. a screw; 504. a clamping block; 505. a slot; 506. a clamping groove.

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; all other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the first embodiment, as shown in fig. 1 to 9, the present invention includes a bus duct body 1, wherein the inside of the bus duct body 1 is equidistantly provided with trough bodies 2, the inside of the trough bodies 2 is provided with a bus duct body 3, the bottom end of the bus duct body 1 is provided with a monitoring component 4, the bottom end of the bus duct body 1 is provided with a mounting component 5, the monitoring component 4 includes monitoring grooves 401 equidistantly provided at the bottom end of the trough bodies 2, the bottom end of the bus duct body 1 is provided with a mounting frame 402, the inside of the mounting frame 402 is uniformly provided with mounting grooves 403, the mounting grooves 403 are adapted to the monitoring grooves 401, the inside of the mounting grooves 403 is provided with a circuit detection unit 404, the circuit detection unit 404 includes a movable block 4041 mounted inside the mounting grooves 403, the inside of the movable block 4041 is provided with a temperature monitoring unit 405, the temperature monitoring unit 405 includes an inner groove 4051 provided inside the movable block 4041, the top end of the inner groove 4051 is provided with a top groove 4052, a connecting rod 4054 is inserted into the top groove 4052, an internal heat-conducting block 4053 is mounted at the bottom end of the connecting rod 4054, the internal heat-conducting block 4053 is located inside the inner groove 4051, an external heat-conducting block 4055 is mounted at the top end of the connecting rod 4054, a first spring 4056 is mounted at the bottom end of the external heat-conducting block 4055, the bottom end of the first spring 4056 is fixedly connected with the top end of the movable block 4041, a monitoring probe 4057 is mounted inside the movable block 4041, one end of the monitoring probe 4057 is electrically connected with a temperature sensor 4058, a first slider 4043 is symmetrically mounted on the front and back of the movable block 4041, the first slider 4043 is slidably connected inside the first sliding groove 4042, the first sliding groove 4042 is symmetrically arranged on the front and back of the mounting groove 403, the exhaust unit 406 is mounted at the bottom end of the movable block 4041, insulating blocks 4044 are symmetrically mounted on two sides of the movable block 4041, a conductive rod 4045 is mounted inside the insulating block 4044, two ends of the conductive rod 4045 are respectively arranged on the top ends of the two insulating blocks 4044, conducting rod 4045 is electrically connected with detection lamp 4046, exhaust unit 406 includes bottom groove 4061 opened at the bottom end of movable block 4041, bottom groove 4061 is internally installed and plugged with piston block 4062, the outer wall of piston block 4062 is closely attached to the inside of bottom groove 4061, second sliding groove 4063 is symmetrically opened on the front and back of bottom groove 4061, the inside sliding connection of second sliding groove 4063 has second slider 4064, second slider 4064 is symmetrically installed on the front and back of piston block 4062, exhaust groove 4065 is symmetrically opened on the inside of piston block 4062, exhaust groove 4065 is arranged in an L-shape, the top end of exhaust groove 4065 penetrates through to the top end of piston block 4062, the other end of exhaust groove 4065 penetrates through to the side wall of piston block 4062, monitoring probe 4057 is installed on the top end of piston block 4062, temperature sensor 4058 is installed on the bottom end of piston block 4062, clamping groove 66 is symmetrically opened on the inner wall of bottom groove 4061, movable grooves 4067 are symmetrically opened on both sides of piston block 4062, a clamping block 4068 is movably mounted in the movable groove 4067, the clamping block 4068 is inserted into the clamping groove 4066, a second spring 4069 is mounted at one end of each of the two clamping blocks 4068 close to each other, one end of the second spring 4069 is fixedly connected with the inner wall of the clamping block 4068, a communicating groove 40610 is formed in the bottom end of the movable groove 4067, a guide groove 40611 is formed in the bottom end of the communicating groove 40610, the guide groove 40611 penetrates through the bottom end of the piston block 4062, a guide rod 40613 is inserted into the guide groove 40611, a rotating rod 40612 is rotatably connected to the top end of the guide rod 40613, the top end of the rotating rod 40612 is rotatably connected with the movable groove 4067, a connecting rod 40614 is mounted between the two guide rods 40613, and the connecting rod 40614 is located below the piston block 4062;

when the bus body 3 works, the external heat conducting block 4055 is attached to the bottom wall of the bus body 3, so that the external heat conducting block 4055 transfers the temperature of the bus body 3 to the inside of the inner groove 4051 through the connecting rod 4054 and the internal heat conducting block 4053, the temperature inside the inner groove 4051 is the same as the temperature of the bus body 3, and then the temperature is transferred to the temperature sensor 4058 through the monitoring probe 4057, so that the temperature sensor 4058 transfers the temperature of the bus body 3 to a receiver, and the bottom end of each bus body 3 is provided with the plurality of temperature sensors 4058, so that the monitoring accuracy of the temperature of each bus body 3 is improved, and the monitoring effect is improved;

when the bus body 3 has a short circuit condition and needs to be overhauled, the movable block 4041 is pushed upwards at the moment, the insulating blocks 4044 on the two sides of the movable block 4041 move upwards, the two ends of the conducting rod 4045 are in contact with the bus body 3, if the short circuit condition occurs on the part of the bus body 3 between the two ends of the conducting rod 4045, the detection lamp 4046 is not on at the moment, and if the short circuit condition does not occur on the part of the bus body 3 between the two ends of the conducting rod 4045, the current passes through the detection lamp 4046, and the detection lamp 4046 is on, so that the short circuit position of the bus body 3 is detected according to the on-off condition of each detection lamp 4046, and the bus body 3 is convenient to be overhauled;

in the maintenance in-process, if the inside atmospheric pressure of movable block 4041 is when great, downwardly pulling guide bar 40613 this moment, make guide bar 40613 the downstream, then drive fixture block 4068 towards the inside removal of movable groove 4067 through bull stick 40612, make fixture block 4068 follow the inside removal of draw-in groove 4066, piston block 4062 breaks away from the joint with bottom groove 4061 this moment, thereby make piston block 4062 the downstream, thereby make the bottom of exhaust groove 4065 remove to the bottom groove 4061 outside, thereby make the inside and external being linked together of movable block 4041, thereby make things convenient for movable block 4041 to remove, thereby the convenient short-circuit condition to generating line body 3 detects.

In the second embodiment, on the basis of the first embodiment, the mounting assembly 5 includes an inserting rod 501 mounted at four corners of the bottom end of the bus duct body 1, a screw groove 502 is formed at the bottom end of the inserting rod 501, a screw 503 is connected to the inner thread of the screw groove 502, clamping blocks 504 are symmetrically mounted on two sides of the screw 503, slots 505 are uniformly formed in the monitoring groove 401, the slots 505 are matched with the inserting rod 501, clamping grooves 506 are symmetrically formed in two sides of the slots 505, and the clamping grooves 506 are matched with the clamping blocks 504;

cooperate slot 505 on the mounting bracket 402 with the inserted bar 501 of bus duct body 1 bottom, and joint groove 506 cooperatees with joint piece 504, make the inserted bar 501 insert the inside of slot 505, rotate screw rod 503 afterwards, make joint piece 504 rotate ninety degrees, and joint piece 504 is located the below of mounting bracket 402, make joint piece 504 support mounting bracket 402, thereby accomplish the installation of mounting bracket 402, mounting groove 403 on the mounting bracket 402 and the monitoring groove 401 looks adaptation of bus duct body 1 bottom this moment, and outside heat conduction piece 4055 hugs closely with 3 diapalls of bus duct body under the spring action of first spring 4056.

Claims

1. The utility model provides a wireless monitoring system of sliding connection type bus duct based on mix network deployment, includes bus duct body (1), its characterized in that: the bus duct comprises a bus duct body (1), and is characterized in that the inside of the bus duct body (1) is equidistantly provided with groove bodies (2), a bus body (3) is arranged inside the groove bodies (2), the bottom end of the bus duct body (1) is provided with a monitoring assembly (4), and the bottom end of the bus duct body (1) is provided with an installation assembly (5);

the monitoring assembly (4) comprises monitoring grooves (401) which are equidistantly formed in the bottom end of the groove body (2), a mounting frame (402) is mounted at the bottom end of the bus duct body (1), mounting grooves (403) are uniformly formed in the mounting frame (402), the mounting grooves (403) are matched with the monitoring grooves (401), and a circuit detection unit (404) is mounted in the mounting grooves (403);

the circuit detection unit (404) comprises a movable block (4041) arranged in the mounting groove (403), and a temperature monitoring unit (405) is arranged in the movable block (4041);

temperature monitoring unit (405) is including offering in inside groove (4051) of movable block (4041), top groove (4052) have been seted up on the top of inside groove (4051), the inside grafting of top groove (4052) has connecting rod (4054), inside heat conduction piece (4053) are installed to the bottom of connecting rod (4054), inside heat conduction piece (4053) are located the inside of inside groove (4051), outside heat conduction piece (4055) are installed on the top of connecting rod (4054), first spring (4056) are installed to the bottom of outside heat conduction piece (4055), the bottom of first spring (4056) and the top fixed connection of movable block (4041), the internally mounted of movable block (4041) has monitoring probe (4057), the one end electric connection of monitoring probe (4057) has temperature sensor (4058).

2. The wireless monitoring system of the sliding connection type bus duct based on the hybrid networking as claimed in claim 1, wherein: first slider (4043) are installed to the front and the back symmetry of movable block (4041), and first slider (4043) sliding connection is in the inside of first spout (4042), and the front and the back of mounting groove (403) are seted up to first spout (4042) symmetry, and exhaust unit (406) are installed to the bottom of movable block (4041).

3. The wireless monitoring system of the sliding connection type bus duct based on the hybrid networking as claimed in claim 1, wherein: insulating block (4044) are installed to the bilateral symmetry of movable block (4041), and the internally mounted of insulating block (4044) has conducting rod (4045), and the top of two insulating blocks (4044) is located respectively at the both ends of conducting rod (4045), and conducting rod (4045) electric connection has detection lamp (4046).

4. The wireless monitoring system of the sliding connection type bus duct based on the hybrid networking as claimed in claim 2, wherein: exhaust unit (406) including offering bottom groove (4061) in movable block (4041) bottom, the internally mounted of bottom groove (4061) is pegged graft and is had piston block (4062), the outer wall of piston block (4062) is hugged closely with the inside in bottom groove (4061), second spout (4063) have been seted up to the front and the back symmetry in bottom groove (4061), the inside sliding connection of second spout (4063) has second slider (4064), second slider (4064) symmetry is installed in the front and the back of piston block (4062).

5. The wireless monitoring system of the sliding connection type bus duct based on the hybrid networking is characterized in that: exhaust groove (4065) have been seted up to the inside symmetry of piston piece (4062), and exhaust groove (4065) sets up and is the L type, and the top of exhaust groove (4065) runs through to the top of piston piece (4062), and the other end of exhaust groove (4065) runs through to the lateral wall of piston piece (4062), and monitor (4057) is installed in the top of piston piece (4062), and temperature sensor (4058) is installed in the bottom of piston piece (4062).

6. The wireless monitoring system of the sliding connection type bus duct based on the hybrid networking is characterized in that: draw-in groove (4066) have been seted up to the symmetry on the inner wall of bottom groove (4061), movable groove (4067) have been seted up to the bilateral symmetry of piston piece (4062), and the inside movable mounting in movable groove (4067) has fixture block (4068), and fixture block (4068) are pegged graft in the inside of draw-in groove (4066), and second spring (4069) are all installed to the one end that two fixture blocks (4068) are close to each other, the inner wall fixed connection of the one end of second spring (4069) and fixture block (4068).

7. The wireless monitoring system of the sliding connection type bus duct based on the hybrid networking as claimed in claim 6, wherein: the bottom in activity groove (4067) has seted up intercommunication groove (40610), guide way (40611) have been seted up to the bottom in intercommunication groove (40610), guide way (40611) run through to the bottom of piston piece (4062), the inside grafting of guide way (40611) has guide bar (40613), the top of guide bar (40613) is rotated and is connected with bull stick (40612), the top and the activity groove (4067) of bull stick (40612) are rotated and are connected, install connecting rod (40614) between two (4013), connecting rod (40614) are located the below of piston piece (4062).

8. The wireless monitoring system of the sliding connection type bus duct based on the hybrid networking as claimed in claim 1, wherein: the mounting component (5) comprises an insert rod (501) mounted at the four corners of the bottom end of the bus duct body (1), a screw groove (502) is formed in the bottom end of the insert rod (501), a screw rod (503) is connected to the inner thread of the screw groove (502), and clamping blocks (504) are symmetrically mounted on two sides of the screw rod (503).

9. The wireless monitoring system of the sliding connection type bus duct based on the hybrid networking according to claim 8, wherein: the monitoring device is characterized in that slots (505) are uniformly formed in the monitoring groove (401), the slots (505) are matched with the insertion rod (501), clamping grooves (506) are symmetrically formed in two sides of the slots (505), and the clamping grooves (506) are matched with the clamping blocks (504).