CN114518160A

CN114518160A - Efficient electronic sensor for large mechanical equipment

Info

Publication number: CN114518160A
Application number: CN202210183982.7A
Authority: CN
Inventors: 时维兵; 宋知春; 胡珀; 神军红
Original assignee: Zhenjiang Yiruite Electromechanical Equipment Co ltd
Current assignee: Zhenjiang Yiruite Electromechanical Equipment Co ltd
Priority date: 2022-02-28
Filing date: 2022-02-28
Publication date: 2022-05-20

Abstract

The invention discloses a high-efficiency electronic sensor for large-scale mechanical equipment, which comprises a support and a fixing assembly, wherein an embedding groove is formed in the lower surface of the support, fixing holes are formed in the periphery above the embedding groove, limiting grooves are symmetrically formed in the left side and the right side above the embedding groove, limiting rods are fixedly connected in the limiting grooves, an embedded plate is fixedly connected below the limiting rods, a fixing groove is formed in the surface of the embedded plate, a shell is arranged below the embedded plate, a sliding cavity is formed in the inner surface of the shell, a limiting cavity is formed in the outer side of the sliding cavity, a sliding plate is slidably connected in the limiting cavity, a sliding block is fixedly connected to the inner side of the sliding plate, a backing plate is fixedly connected to the inner side of the sliding block, a buffer spring is fixedly connected to the outer side of the backing plate, and the fixing assembly for fixing the shell is arranged on the periphery of the shell. The invention can carry out omnibearing detection on the vibration condition of the device when the device is used by matching parts of each part, thereby ensuring the detection precision and efficiency.

Description

Efficient electronic sensor for large mechanical equipment

Technical Field

The invention relates to the technical field of electronic sensors, in particular to a high-efficiency electronic sensor for large-scale mechanical equipment.

Background

Electronic sensors are used to detect various physical quantities of a given physical system, these quantities being: temperature, light (photo), magnetic field, strain pressure, displacement, and rotational acceleration. It may also be defined as a device that receives power from one system, usually in another form, and sends power to a second system, and many types of electronic sensors, such as shock sensors, are used on large mechanical devices.

After the existing vibration sensor on the market is installed on mechanical equipment, under the long-time operation of the mechanical equipment, the precision may be reduced due to the loose internal structure, and therefore, a high-efficiency electronic sensor for large-scale mechanical equipment is provided.

Disclosure of Invention

The present invention is directed to a high-efficiency electronic sensor for large-scale mechanical equipment, which solves the above problems.

In order to achieve the purpose, the invention provides the following technical scheme: a high-efficiency electronic sensor for large-scale mechanical equipment comprises a bracket and a fixing component, wherein the lower surface of the bracket is provided with an embedding groove, and the periphery above the caulking groove is provided with a fixing hole, the left side and the right side above the caulking groove are symmetrically provided with a limiting groove, a limiting rod is fixedly connected in the limiting groove, an embedded plate is fixedly connected below the limiting rod, a fixing groove is arranged on the surface of the embedded plate, a shell is arranged below the embedded plate, a sliding cavity is arranged on the inner surface of the shell, a limiting cavity is arranged on the outer side of the sliding cavity, a sliding plate is connected in the limiting cavity in a sliding manner, a slide block is fixedly connected on the inner side of the slide plate, a backing plate is fixedly connected on the inner side of the slide block, a stabilizing spring is fixedly connected between the slide block and the slide cavity, a buffer spring is fixedly connected on the outer side of the backing plate, and a balancing weight is fixedly connected between the buffer springs and used for fixing the shell, and the fixing assembly is arranged around the shell.

Furthermore, six surface central authorities of balancing weight all fixedly connected with sleeves, and the inside fixedly connected with transmitter of sleeve, the spout has been seted up to the sleeve inner wall, and the embedding of spout is connected with the sliding ring, sliding ring top fixedly connected with sleeve pipe, and the inside fixedly connected with receiver of sleeve pipe.

Furthermore, the sleeve is connected with the sleeve in a sliding mode through a sliding ring and a sliding groove, and the sleeve is fixedly connected with the base plate.

Further, fixed subassembly includes draw-in groove, cardboard, card hole, fixing bolt, fixture block, fixed spring, fixed frame and card rail, the gomphosis is connected with the cardboard in the draw-in groove, and the cardboard surface is provided with the card hole, the downthehole threaded connection of card has fixing bolt, cardboard below fixedly connected with fixture block, and cardboard outside fixedly connected with fixed spring, the fixed frame of fixedly connected with in the fixed spring outside, and fixed frame lower surface has seted up the card rail.

Furthermore, the cardboard passes through the draw-in groove and is connected with the casing gomphosis, and the cardboard passes through fixed spring and fixed frame elastic connection.

Furthermore, the clamping block is in sliding connection with the fixing frame through the clamping rail, and the fixing frame is fixedly connected with the support.

Furthermore, the panel is connected with the support in a jogged mode through the caulking groove, and the limiting rod is connected with the limiting groove in a sliding mode through the panel.

Furthermore, the balancing weight is elastically connected with the backing plate through a buffer spring, and the backing plate is elastically connected with the shell through a sliding block and a stabilizing spring.

The invention provides a high-efficiency electronic sensor for large-scale mechanical equipment, which has the following beneficial effects: the high-efficiency electronic sensor for the large-scale mechanical equipment can detect the vibration condition of the device in all directions by matching parts of each part when the device is used, so that the detection precision and efficiency are ensured;

1. according to the invention, through the arrangement of the limiting rod, when the device is installed, the limiting rod can be inserted into the limiting groove to position the device, so that the situation that the panel is not embedded into the caulking groove and cannot be fixed is avoided, and the limiting rod can be matched with the limiting groove to limit the panel, so that the panel is prevented from shaking in the caulking groove;

2. according to the invention, through the arrangement of the emitter, when the equipment runs, the counter weight block can be in relative motion with the shell through the inertia of the elastic support of the buffer spring, so that the sleeve can slide in the sleeve, the receiver measures the moving distance of the sleeve through the emitter, and the vibration condition of the device is obtained, and the stable spring can provide balanced pulling force for the sliding block, so that the sliding plate is always tightly attached to the limiting cavity when the counter weight block moves;

3. According to the invention, through the arrangement of the fixing component, when the device is installed, the clamping block is firstly stirred in the clamping rail to slide the clamping plate into the fixing frame, after the panel is embedded into the embedding groove, the clamping block is loosened, the clamping plate is reset under the action of the fixing spring and is embedded with the shell through the clamping groove, then the fixing bolt is screwed into the bracket through the clamping hole, the fixing groove and the fixing hole, and the shell is also doubly fixed through the clamping plate while the panel is fixed.

Drawings

FIG. 1 is a schematic cross-sectional front view of the present invention;

FIG. 2 is an enlarged schematic view of the structure at A in FIG. 1 according to the present invention;

FIG. 3 is a schematic perspective view of the housing of the present invention;

FIG. 4 is a cross-sectional front view of the sleeve of the present invention;

fig. 5 is a schematic perspective view of the sleeve of the present invention.

In the figure: 1. a support; 2. caulking grooves; 3. a fixing hole; 4. a limiting groove; 5. a limiting rod; 6. a panel; 7. fixing grooves; 8. a housing; 9. a slide chamber; 10. a limiting cavity; 11. a slide plate; 12. a slider; 13. a base plate; 14. a stabilizing spring; 15. a buffer spring; 16. a balancing weight; 17. a sleeve; 18. a transmitter; 19. a chute; 20. a slip ring; 21. a sleeve; 22. a receiver; 23. a fixing assembly; 2301. a card slot; 2302. clamping a plate; 2303. a clamping hole; 2304. fixing the bolt; 2305. a clamping block; 2306. fixing the spring; 2307. a fixing frame; 2308. and (5) clamping the rail.

Detailed Description

As shown in fig. 1, fig. 2, fig. 3, fig. 4 and fig. 5, a high-efficiency electronic sensor for large-scale mechanical equipment comprises a support 1 and a fixing component 23, wherein an embedding groove 2 is formed on the lower surface of the support 1, fixing holes 3 are formed around the upper part of the embedding groove 2, limiting grooves 4 are symmetrically formed on the left side and the right side of the upper part of the embedding groove 2, a limiting rod 5 is fixedly connected in each limiting groove 4, an embedded plate 6 is fixedly connected below each limiting rod 5, a fixing groove 7 is formed in the surface of each embedded plate 6, a shell 8 is arranged below each embedded plate 6, a sliding cavity 9 is formed in the inner surface of each shell 8, a limiting cavity 10 is arranged on the outer side of each sliding cavity 9, a sliding plate 11 is slidably connected in each limiting cavity 10, a sliding block 12 is fixedly connected to the inner side of each sliding plate 11, a backing plate 13 is fixedly connected to the inner side of each sliding block 12, a stabilizing spring 14 is fixedly connected between each sliding block 12 and the sliding cavity 9, and a buffer spring 15 is fixedly connected to the outer side of each backing plate 13, and fixedly connected with balancing weight 16 between the buffer spring 15, a fixed subassembly 23 for fixing the shell 8 sets up around the shell 8, panel 6 is connected with support 1 gomphosis through caulking groove 2, and gag lever post 5 passes through panel 6 and spacing groove 4 sliding connection, balancing weight 16 passes through buffer spring 15 and backing plate 13 elastic connection, and backing plate 13 passes through slider 12 and stabilizing spring 14 and shell 8 elastic connection, through the setting of gag lever post 5, make when installing the device, can insert gag lever post 5 into spacing groove 4 and fix the device, avoid panel 6 not imbed caulking groove 2 and can't fix the device, and gag lever post 5 can cooperate the spacing groove 4 to restrict panel 6, avoid panel 6 to rock in caulking groove 2.

As shown in fig. 1, 4 and 5, a sleeve 17 is fixedly connected to the center of six outer surfaces of a counterweight 16, a transmitter 18 is fixedly connected to the inside of the sleeve 17, a sliding groove 19 is formed in the inner wall of the sleeve 17, a sliding ring 20 is embedded and connected in the sliding groove 19, a sleeve 21 is fixedly connected to the upper side of the sliding ring 20, a receiver 22 is fixedly connected to the inside of the sleeve 21, the sleeve 21 is slidably connected to the sleeve 17 through the sliding ring 20 and the sliding groove 19, the sleeve 21 is fixedly connected to a backing plate 13, and by the arrangement of the transmitter 18, when the device is operated, the counterweight 16 can move relative to the housing 8 by the inertia elastically supported by the buffer spring 15, so that the sleeve 21 slides in the sleeve 17, the receiver 22 measures the moving distance of the sleeve 21 through the transmitter 18, thereby obtaining the vibration condition of the device, and the stabilizing spring 14 can provide a balanced pulling force for the slider 12, thereby ensuring that the sliding plate 11 is always tightly attached to the limiting cavity 10 when the balancing weight 16 moves.

As shown in fig. 1, 2 and 3, the fixing member 23 includes a clamping groove 2301, a clamping plate 2302, a clamping hole 2303, a fixing bolt 2304, a clamping block 2305, a fixing spring 2306, a fixing frame 2307 and a clamping rail 2308, the clamping plate 2302 is embedded in the clamping groove 2301, the clamping hole 2303 is formed in the surface of the clamping plate 2302, the fixing bolt 2304 is connected with the clamping hole 2303 through an internal thread, the clamping block 2305 is fixedly connected below the clamping plate 2302, the fixing spring 2306 is fixedly connected to the outer side of the clamping plate 2306, the fixing frame 2307 is fixedly connected to the outer side of the fixing spring 2306, the clamping rail 2308 is formed in the lower surface of the fixing frame 2307, the clamping plate 2302 is elastically connected with the fixing frame 2308 through the fixing spring 2306, the clamping block 2305 is slidably connected with the fixing frame 2307 through the clamping rail 2308, the fixing frame 2307 is fixedly connected with the bracket 1, the fixing member 23 is arranged, so that when the installation device is used, the clamping block 2305 is pulled to slide the clamping plate 2302 into the fixing frame 2307, after panel 6 is embedded into caulking groove 2, loosen fixture block 2305, cardboard 2302 resets under the effect of fixed spring 2306, through draw-in groove 2301 and outer casing 8 gomphosis, again with fixing bolt 2304 through calorie hole 2303, fixed slot 7 and fixed hole 3 twist in support 1, when fixing panel 6, also carry out dual fixed through cardboard 2302 to outer casing 8.

In summary, when the high-efficiency electronic sensor for large-scale mechanical equipment is used, firstly, according to the structure shown in fig. 1, fig. 2, fig. 3, fig. 4 and fig. 5, the clamping block 2305 is poked in the clamping rail 2308 to slide the clamping plate 2302 into the fixing frame 2307, the limiting rod 5 is inserted into the limiting groove 4 to position the device, the panel 6 is prevented from being embedded into the embedding groove 2 and being incapable of fixing the device, the limiting rod 5 can be matched with the limiting groove 4 to limit the panel 6, the panel 6 is prevented from shaking in the embedding groove 2, after the panel 6 is embedded into the embedding groove 2, the clamping block 2305 is loosened, the clamping plate 2302 is reset under the action of the fixing spring 2306, the clamping groove 2301 is embedded with the casing 8, the fixing bolt 2304 is screwed into the bracket 1 through the clamping hole 2303, the fixing groove 7 and the fixing hole 3, the clamping plate 2302 is used for double fixing the casing 8, when the equipment is in operation, the balancing weight 16 can take place relative motion by buffer spring 15 elastic support's inertia and shell 8 to make sleeve 21 slide in sleeve 17, receiver 22 measures the distance that sleeve 21 removed through transmitter 18, thereby reachs the vibrations condition of device, and stabilizing spring 14 can provide balanced pulling force for slider 12, thereby spacing chamber 10 is hugged closely all the time to slide 11 when guaranteeing balancing weight 16 to remove.

Claims

1. A high-efficiency electronic sensor for large-scale mechanical equipment comprises a support (1) and a fixing assembly (23) and is characterized in that an embedding groove (2) is formed in the lower surface of the support (1), fixing holes (3) are formed in the periphery above the embedding groove (2), limiting grooves (4) are symmetrically formed in the left side and the right side of the upper portion of the embedding groove (2), limiting rods (5) are fixedly connected into the limiting grooves (4), a panel (6) is fixedly connected to the lower portion of each limiting rod (5), a fixing groove (7) is formed in the surface of the panel (6), a shell (8) is arranged below the panel (6), a sliding cavity (9) is formed in the inner surface of the shell (8), a limiting cavity (10) is formed in the outer side of the sliding cavity (9), a sliding plate (11) is slidably connected into the limiting cavity (10), and a sliding block (12) is fixedly connected to the inner side of the sliding plate (11), slider (12) inboard fixedly connected with backing plate (13), and fixedly connected with stabilizing spring (14) between slider (12) and smooth chamber (9), backing plate (13) outside fixedly connected with buffer spring (15), and fixedly connected with balancing weight (16) between buffer spring (15) for fixed shell (8) fixed subassembly (23) set up around shell (8).

2. The efficient electronic sensor for the large-scale mechanical equipment as recited in claim 1, wherein a sleeve (17) is fixedly connected to the center of each of six outer surfaces of the counterweight (16), a transmitter (18) is fixedly connected to the inside of the sleeve (17), a sliding groove (19) is formed in the inner wall of the sleeve (17), a sliding ring (20) is embedded and connected in the sliding groove (19), a sleeve (21) is fixedly connected to the upper side of the sliding ring (20), and a receiver (22) is fixedly connected to the inside of the sleeve (21).

3. The high-efficiency electronic sensor for the large-scale mechanical equipment as claimed in claim 2, wherein the sleeve (21) is connected with the sleeve (17) in a sliding way through a sliding ring (20) and a sliding groove (19), and the sleeve (21) is fixedly connected with the backing plate (13).

4. The efficient electronic sensor for the large-scale mechanical equipment as recited in claim 1, wherein the fixing component (23) comprises a clamping groove (2301), a clamping plate (2302), a clamping hole (2303), a fixing bolt (2304), a clamping block (2305), a fixing spring (2306), a fixing frame (2307) and a clamping rail (2308), the clamping plate (2302) is embedded and connected in the clamping groove (2301), the clamping hole (2303) is formed in the surface of the clamping plate (2302), the fixing bolt (2304) is connected in the clamping hole (2303) in an internal thread manner, the clamping block (2305) is fixedly connected below the clamping plate (2302), the fixing spring (2306) is fixedly connected in the outer side of the fixing spring (2307), and the clamping rail (2308) is formed in the lower surface of the fixing frame (2307).

5. The high-efficiency electronic sensor for the large-scale mechanical equipment is characterized in that the clamping plate (2302) is in embedded connection with the outer shell (8) through the clamping groove (2301), and the clamping plate (2302) is elastically connected with the fixing frame (2307) through the fixing spring (2306).

6. The high-efficiency electronic sensor for large-scale mechanical equipment according to claim 4, wherein the clamping block (2305) is slidably connected with the fixing frame (2307) through a clamping rail (2308), and the fixing frame (2307) is fixedly connected with the bracket (1).

7. The high-efficiency electronic sensor for the large-scale mechanical equipment is characterized in that the panel (6) is connected with the bracket (1) in a jogged mode through the embedded groove (2), and the limiting rod (5) is connected with the limiting groove (4) in a sliding mode through the panel (6).

8. The high-efficiency electronic sensor for the large-scale mechanical equipment, according to claim 1, is characterized in that the balancing weight (16) is elastically connected with the backing plate (13) through a buffer spring (15), and the backing plate (13) is elastically connected with the shell (8) through a sliding block (12) and a stabilizing spring (14).