CN220565307U - Vibration sensor burying device - Google Patents

Abstract

The utility model discloses a vibration sensor embedding device, which comprises a main body support, wherein a grooving device is arranged in the main body support, a winding wheel is arranged on the inner side of the grooving device, the main body support comprises a fixing frame, a fixed pulley capable of adjusting the vertical height is arranged in the middle of the fixing frame, the winding wheel is arranged in the middle of a second guiding groove, a vibration cable or a vibration sensor wire is wound in the winding wheel.

Description

Vibration sensor burying device

Technical Field

The utility model relates to the technical field of vibration sensors, in particular to a vibration sensor embedding device.

Background

A vibration sensor is a common security device that can detect whether a person or object has entered a set area by sensing vibrations of the surrounding environment. When the vibration sensor detects that the vibration of the surrounding environment exceeds a set threshold value, an alarm is triggered to inform security personnel or owners of processing, and when the conditions of artificial damage, wall crossing, vehicle stepping point parking and the like occur, the alarm device is triggered.

The vibration sensor comprises a piezoelectric type device, an eddy current type device, a vibration cable device, a vibration optical cable device and the like, but no matter what type of device for collecting vibration frequency is, especially when the vibration optical cable device for collecting vibration is arranged in a main body, the device is prevented from being damaged due to the installation mode of the buried device, so that corresponding wires are buried underground, the conventional buried mode is that after a buried route is planned, the grooves are required to be dug first, then the cables are arranged last, and then the wires are buried.

The existing equipment for burying the wires is mainly characterized in that a groove is dug out on the ground by adopting equipment called a wire burying groove machine, and then the wires are buried in the groove, for example, the application number is as follows: CN202111180141.2, which is capable of trenching, requires manual operation in the subsequent wire burying process, is inconvenient in the wire withdrawing process during wire replacement or maintenance, and in view of the above problems, particularly provides a vibration sensor burying device.

Disclosure of Invention

The present utility model is directed to a vibration sensor burying device, which solves the above-mentioned problems.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the vibration sensor embedding device comprises a main body support, wherein a grooving device is arranged in the main body support, and a winding wheel is arranged on the inner side of the grooving device;

the main body support comprises a first fixing frame, and a fixed pulley capable of adjusting the vertical height is arranged in the middle of the first fixing frame;

the grooving device comprises a cutting machine capable of lifting at the inner side of the front end of the first fixing frame, a cutting wheel is connected to the bottom of the cutting machine in a driving mode, a protective cover is sleeved outside the cutting wheel, a blocking cover is arranged at the centrifugal end of the cutting wheel in the rotating direction, and a second guide groove is arranged at the outer side of the blocking cover in the backward direction;

the winding wheel is assembled in the middle of the second guide groove, the inner side of the first fixing frame, and the vibration cable or the vibration sensor wire is wound in the winding wheel.

Preferably, at least 4 guide wheels for walking are arranged at the bottom of the first fixing frame, and at least 2 guide wheels are steering guide wheels capable of steering.

Preferably, the front end and the middle part of the first fixing frame are respectively provided with a first guide rod and a second guide rod, the outer side of the winding wheel is provided with a sleeve structure, and the sleeve structure can be lifted and lowered outside the first guide rod.

Preferably, the second fixing frame is arranged outside the protective cover, the adjusting frame is arranged outside the second fixing frame, the adjusting frame is arranged on the outer surface of the second guide rod, and the adjusting frame can be lifted relative to the second guide rod.

Preferably, the cutting wheel runs through the protection casing and is equipped with belt conveying mechanism, belt conveying mechanism's top center department is equipped with driving motor, driving motor and the top fixed assembly of second mount, the surface of cutting wheel evenly shaping has the sawtooth, and the outside of cutting wheel evenly welds there is helical blade.

Preferably, the inside welding of protection casing has curved soil separating board, separates the soil separating board and is inside and outside two sections, and the middle part of adjacent two sections soil separating board sets up in the outside of heliciform blade.

Preferably, an inclined first guide groove is welded below the blocking cover, and the first guide groove is communicated with the second guide groove.

Preferably, the outside of the non-steering guide wheel is provided with a chain wheel structure, the outside of the axle center of the winding wheel is also provided with a chain wheel structure, the outsides of the two sets of chain wheel structures are sleeved with chains, and the outside of the chains, which is positioned outside the first fixing frame, is provided with a tensioner.

Preferably, the front end of the first fixing frame is provided with an outer shell skin, the middle and rear ends of the first fixing frame are provided with a protective net, and the top end of the first fixing frame is provided with a handle.

Preferably, the discharge opening of the second guide groove corresponds to the center line of the cutting wheel.

Compared with the prior art, the utility model has the beneficial effects that: the utility model provides a vibration sensor embedding device with a cutting machine capable of lifting and a winding wheel 2 with a lead function;

the device has the integrated structure of grooving and wire burying and backfilling, so that the wires or vibration cables can be directly buried on the ground with the required depth as long as the pushing device moves, the device can also be directly operated again, the automatic recovery of the wires can be realized through the arrangement with different depths in the same way, and the problems of overlong wires and inconvenient burying and taking of the wires when the vibration sensor is buried are solved;

besides being applied to burying and taking out of a vibration cable or a vibration sensor, the utility model can also be applied to the construction process of a buried cable, and has strong adaptability.

Drawings

Fig. 1 is a schematic view of the working state of the present utility model.

Fig. 2 is a schematic diagram of the overall structure of the present utility model.

FIG. 3 is a schematic diagram of the working procedure of the present utility model.

Fig. 4 is a schematic view of the overall structure of the present utility model from the bottom perspective.

FIG. 5 is a schematic view of the grooving apparatus of the present utility model from a cut-away assembly perspective.

Fig. 6 is a schematic diagram illustrating a cutting assembly view of the grooving apparatus according to the present utility model.

In the figure: 1. the main body comprises a main body support, 11, a first fixing frame, 12, guide wheels, 13, a first guide rod, 14, a second guide rod, 15, an adjusting rod, 16, a fixed pulley, 2, a winding wheel, 3, a grooving device, 31, a second fixing frame, 32, an adjusting frame, 33, a driving motor, 34, a belt conveying mechanism, 35, a cutting wheel, 36, a protective cover, 37, a soil isolation plate, 38, a first guide groove, 39, a blocking cover, 310 and a second guide groove.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-6, the present utility model provides a technical solution: the vibration sensor embedding device comprises a main body bracket 1, wherein a grooving device 3 is arranged in the main body bracket 1, and a winding wheel 2 is arranged on the inner side of the grooving device 3;

the main body bracket 1 comprises a first fixing bracket 11, and a fixed pulley 16 capable of adjusting the vertical height is arranged in the middle of the first fixing bracket 11;

the grooving device 3 comprises a cutting machine capable of lifting and falling on the inner side of the front end of the first fixing frame 11, a cutting wheel 35 is connected to the bottom of the cutting machine in a driving way, a protective cover 36 is sleeved outside the cutting wheel 35, a blocking cover 39 is arranged at the centrifugal end of the cutting wheel 35 in the rotating direction, and a second guiding groove 310 is arranged on the outer side of the blocking cover 39 backwards;

the winding wheel 2 is assembled in the middle of the second guide groove 310, the inner side of the first fixing frame 11, and a vibration cable or a vibration sensor wire is wound in the winding wheel 2.

The utility model provides a vibration sensor embedding device with a cutting machine capable of lifting and a winding wheel 2 with a lead function;

when the vibration sensor needs to be buried, firstly, the winding wheel 2 is taken down, the winding wheel with the lead is assembled at the original position, the lead is pulled out, the tail end is fixed at the required position, then a burying route is planned, the planned burying route is marked, the burying depth is determined, after the burying depth is determined, a motor is started to drive the cutting wheel 35 to rotate, the adjusting frame 32 drives the cutting machine to move downwards until the cutting depth is reached, after the cutting depth is reached, the cutting wheel 35 cuts soil to bring up the helical blades, the soil is intercepted by the arc-shaped soil isolation plate 37 and the blocking cover 39 under the action of centrifugal force, and moves backwards through the first guide groove 38 and the second guide groove 310;

and then the whole device is pushed to walk along the planned path mark, as shown in fig. 3, in the process of advancing the cutting wheel, the soil lifted by cutting can move backwards to the rear position through the second guiding groove 310, so that the wires guided downwards by the fixed pulley 16 are buried in the grooves cut by the front cutting wheel 35, the vibration sensor or the wires are laid in the form of edge cutting burial, and the laying process is uniform and quick.

When the vibration sensor or the vibration sensor wire is required to be taken out, the cutting depth of the cutting wheel 35 is adjusted to be 5-10 cm in the original cutting position, one end of the wire is fixed in the empty winding wheel 2, then the whole device is pushed to walk forwards, the groove is cut firstly, the wire is pulled out later, and finally the wire is automatically recovered in a mode of directly backfilling soil.

Specifically, the bottom of the first fixing frame 11 is equipped with at least 4 guide wheels 12 for walking, and at least 2 guide wheels 12 are steering guide wheels capable of steering, 2 rotatable guide wheels 12 are used for assisting the whole machine to steer, the running direction of equipment is convenient to control, the tire width and the tire texture of the guide wheels 12 are required to be determined according to the road surface material using the road surface, and the embedded scene is mostly buried in soil, so that the stability of the whole running process can be ensured by using the tires with wide and deep textures.

Specifically, the front end and the middle part of the first fixing frame 11 are respectively provided with a first guide rod 13 and a second guide rod 14, the outer side of the winding wheel 2 is provided with a sleeve structure, the sleeve structure can be lifted and lowered outside the first guide rod 13, the guide rod and the corresponding sleeve structure or the adjusting frame 32 structure can be fixed in a plurality of modes to achieve unlocking adjusting positions and locking, the conventional scheme is that bolts are used for being connected with the outer side of the sleeve structure or the adjusting frame 32 in a threaded mode to be propped against the outer side of the guide rod for fixing, the shaft pin positions arranged at the fixing positions can be used for positioning, the method is a conventional means for adjusting depth, chain driving or four-cylinder driving electric adjusting lifting can be used, and an electric driving mode refers to a lifting mechanism of the automatic tree planter.

Specifically, the second fixing frame 31 is assembled outside the protective cover 36, the adjusting frame 32 is assembled on the outer side of the second fixing frame 31, the adjusting frame 32 is assembled on the outer surface of the second guide rod 14, the adjusting frame 32 can be lifted relative to the second guide rod 14, the soil isolation plate 37 is arranged to intercept soil under the condition that the rotation of the cutting wheel 35 is not influenced to the greatest extent when the cutting wheel rotates to cut the ground to bring the soil up, the soil is convenient for subsequent backfilling operation, as shown in fig. 3, the soil can be influenced by the cutting wheel 35 rotating clockwise, the soil firstly falls to each part of the first guide groove 38 after being buffered by the arc-shaped soil isolation plate 37 and the blocking cover 39, then moves to the second guide groove 310 through the first guide groove 38, the front and rear heights of the second guide groove 310 have a certain fall, and a front high and rear low structure is formed, and the backfilling of the soil is facilitated.

Specifically, the cutting wheel 35 is equipped with the belt conveying mechanism 34 through the protection casing 36, the top center of the belt conveying mechanism 34 is equipped with the driving motor 33, the top fixed assembly of driving motor 33 and second mount 31, the surface of cutting wheel 35 evenly forms the sawtooth, and the outside of cutting wheel 35 evenly welds the helical blade, the cutting wheel 35 is according to the actual face of burying needs to carry out the change of adaptability, as shown in fig. 5 and 6, cutting wheel 35 is applicable to the soil structure that has certain hardness, use the sawtooth to be convenient for cut the soil surface layer, and use helical blade then be favorable to lifting soil, still can use the cutting wheel 35 that both sides set up helical blade at some soft higher operation face of humidity to process, and when retrieving, if original buried road surface laid cement road surface or asphalt road surface, can increase one set or two sets of cutting machines at the front end of main part support 1, after cutting the road surface out the recess, in the corresponding recess position that installs between cutting machine and the cutting machine of this utility model, increase one and like the hoe of agricultural plough, make the cement that both sides cut the both sides form face upwards or the asphalt road surface to promote, the soil is turned over to the place when the soil is satisfied smoothly, the soil is turned over again, the position is turned over again, when the soil is satisfied.

Specifically, an arc-shaped soil isolation plate 37 is welded inside the protective cover 36, the soil isolation plate 37 is of an inner section and an outer section, and the middle parts of the adjacent two sections of soil isolation plates 37 are arranged on the outer sides of the spiral blades.

Specifically, an inclined first guiding groove 38 is welded below the blocking cover 39, the first guiding groove 38 is mutually communicated with the second guiding groove 310, as shown in fig. 1, 3, 5 and 6, the first guiding groove 38 and the second guiding groove are mutually communicated and have a certain inclined downward inclination, soil can be driven to move along the groove body through vibration generated by cutting equipment, the shape of the overlooking angle of the first guiding groove 38 and the second guiding groove 310 is C-shaped, raised soil can bypass a wiring position to be backfilled backwards, a straight groove can be directly used, and by adding 2 groups of fixed pulleys 16, 3 groups of fixed pulleys 16 are beneficial to guide wires outside the winding wheel 2 to be downwards turned to a horizontal position from one side of the groove body firstly, then the wires are downwards perpendicular to the straight groove through one group of pulleys in a turning mode, finally the wires are guided to a direction parallel to the straight groove through one fixed pulley 16, so that the raised soil can bypass the straight groove, and the wires can be completely arranged before the backfilled soil falls.

Specifically, the outside of the non-steering guide wheel 12 is provided with a chain wheel structure, the outside of the axle center of the winding wheel 2 is also provided with a chain wheel structure, the outsides of the two sets of chain wheel structures are sleeved with a chain, the outsides of the chains are provided with tensioners outside the first fixing frame 11, the tensioners are two sets and are respectively meshed with the outside and the inside of the chain to realize the same-direction guiding mode, the tensioning effect is improved, when the winding wheel 2 is required to be regulated according to the use requirement and the position of the anti-skid cover 36 is avoided, the structure of the driving wheel can be kept constantly through the tensioning effect to drive the winding wheel 2 to rotate, so that the winding wheel 2 which rotates unidirectionally is realized through changing the winding direction of the spool in the displacement process, and the wire releasing state is realized in the anticlockwise winding condition, so that the wire releasing speed synchronous with the running speed of equipment is realized, and the wire is always kept straight inside the groove of the fixed pulley 16 in the releasing and winding process, and the wire is prevented from being loosened and cut off by the cutting wheel 35;

when the wire is recovered, referring to fig. 3, the wire is wound up from the right to the left, and the advancing direction is the right direction in fig. 3, and the wire is wound up from the left side of the fixed sheave 16 to the clockwise direction in the same rotational direction as the guide sheave 12 after being exposed from the soil from the right to the right.

Specifically, the front end of the first fixing frame 11 is provided with an outer shell skin, the middle rear end of the first fixing frame 11 is provided with a protective net, the top end of the first fixing frame 11 is provided with a handle, the top end of the fixed pulley 16 is rotatably provided with an adjusting rod 15, the top of the adjusting rod 15 is arranged at the top of the first fixing frame 11, the lifting of the adjusting rod 15 can be adjusted through the sliding of a sleeve opening and the adjusting rod 15 and the cooperation of a jackscrew structure, the adjusting rod 15 can be sheared to be fixed or unlocked by the jackscrew structure, and the problem of adjusting the downward supporting depth of the fixed pulley 16 is solved.

Specifically, the discharge port of the second guide groove 310 corresponds to the center line of the cutting wheel 35, the second guide groove 310 may be provided as a backfill type opening, or may be directly discharged by using the first guide groove 38, the soil is uniformly stacked around the groove, direct burying is not selected, and according to the actual length of the actual second guide groove 310, a screw conveyor or a conveyor belt may be added inside the second guide groove to backward transport the soil in order to secure the best soil transport effect.

Working principle: when the vibration sensor needs to be buried, firstly, the winding wheel 2 is taken down, the winding wheel with the lead is assembled at the original position, the lead is pulled out, the tail end is fixed at the required position, then a burying route is planned, the planned burying route is marked, the burying depth is determined, after the burying depth is determined, a motor is started to drive the cutting wheel 35 to rotate, the adjusting frame 32 drives the cutting machine to move downwards until the cutting depth is reached, after the cutting depth is reached, the cutting wheel 35 cuts soil to bring up the helical blades, the soil is intercepted by the arc-shaped soil isolation plate 37 and the blocking cover 39 under the action of centrifugal force, and moves backwards through the first guide groove 38 and the second guide groove 310;

the whole equipment is then pushed to walk along the planned path mark, in the process of the advancing of the cutting wheel, the soil lifted by cutting can move backwards to the rear position through the second guiding groove 310, so that the wires guided downwards by the fixed pulley 16 are buried in the grooves cut by the front cutting wheel 35, the vibration sensor or the wires are laid in the form of edge cutting burial, and the laying process is uniform and quick.

When the vibration sensor or the vibration sensor wire is required to be taken out, the cutting depth of the cutting wheel 35 is adjusted to be 5-10 cm in the original cutting position, one end of the wire is fixed in the empty winding wheel 2, then the whole device is pushed to walk forwards, the groove is cut firstly, the wire is pulled out later, and finally the wire is automatically recovered in a mode of directly backfilling soil.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (10)

1. The utility model provides a vibration sensor buries device, includes main part support (1), its characterized in that: a grooving device (3) is arranged in the main body support (1), and a winding wheel (2) is arranged on the inner side of the grooving device (3);

the main body support (1) comprises a first fixing frame (11), and a fixed pulley (16) capable of adjusting the vertical height is arranged in the middle of the first fixing frame (11);

the grooving device (3) comprises a cutting machine capable of lifting and falling on the inner side of the front end of the first fixing frame (11), a cutting wheel (35) is connected to the bottom of the cutting machine in a driving mode, a protective cover (36) is sleeved outside the cutting wheel (35), a blocking cover (39) is assembled at the centrifugal end of the cutting wheel (35) in the rotating direction, and a second guiding groove (310) is assembled on the outer side of the blocking cover (39) backwards;

the winding wheel (2) is assembled in the middle of the second guide groove (310), the inner side of the first fixing frame (11) is wound with a vibration cable or a vibration sensor wire inside the winding wheel (2).

2. The shock sensor burying device according to claim 1, wherein: the bottom of the first fixing frame (11) is provided with at least 4 guide wheels (12) for walking, and at least 2 guide wheels (12) are steering guide wheels capable of steering.

3. The shock sensor burying device according to claim 1, wherein: the front end and the middle part of the first fixing frame (11) are respectively provided with a first guide rod (13) and a second guide rod (14), the outer side of the winding wheel (2) is provided with a sleeve structure, and the sleeve structure can be lifted and lowered outside the first guide rod (13).

4. A shock sensor burying device as claimed in claim 3, wherein: the outside of protection casing (36) is equipped with second mount (31), the outside of second mount (31) is equipped with alignment jig (32), alignment jig (32) are assembled at the surface of second guide arm (14), and alignment jig (32) can go up and down relative second guide arm (14).

5. The shock sensor burying device according to claim 1, wherein: cutting wheel (35) run through protection casing (36) and are equipped with belt conveying mechanism (34), belt conveying mechanism (34) top center department is equipped with driving motor (33), driving motor (33) and the top fixed assembly of second mount (31), the surface of cutting wheel (35) evenly shaping has the sawtooth, and the outside of cutting wheel (35) evenly welds the blade of heliciform.

6. The shock sensor burying device according to claim 1, wherein: the inside welding of protection casing (36) has curved soil separating board (37), separates soil separating board (37) and is inside and outside two sections, and the middle part of adjacent two sections soil separating board (37) sets up in the outside of heliciform blade.

7. The shock sensor burying device according to claim 1, wherein: an inclined first guide groove (38) is welded below the blocking cover (39), and the first guide groove (38) and the second guide groove (310) are communicated with each other.

8. The shock sensor burying device according to claim 2, wherein: the outside that non-turned guide pulley (12) was equipped with sprocket structure, and the axle center department outside of rolling wheel (2) also is equipped with sprocket structure, and the outside of two sets of sprocket structures has cup jointed the chain, and the outside that the outside of chain was located first mount (11) is equipped with the tensioning ware.

9. The shock sensor burying device according to claim 1, wherein: the front end of the first fixing frame (11) is provided with an outer shell skin, the middle rear end of the first fixing frame (11) is provided with a protective net, the top end of the first fixing frame (11) is provided with a handle, the top end of the fixed pulley (16) is rotatably provided with an adjusting rod (15), and the top of the adjusting rod (15) is assembled at the top of the first fixing frame (11).

10. The shock sensor burying device according to claim 1, wherein: the discharge opening of the second guide groove (310) corresponds to the center line of the cutting wheel (35).