CN220361225U - Vibration sensor coil recovery device - Google Patents

Abstract

The utility model relates to the technical field of vibration sensors, in particular to a vibration sensor coil recovery device which comprises a receiving bottom box, wherein a crushing square tank is fixedly installed on the receiving bottom box, a feeding notch is formed in the upper end of the crushing square tank, an extrusion crushing mechanism is arranged on the crushing square tank, a fragment cleaning mechanism is arranged above the receiving bottom box, the extrusion crushing mechanism comprises fixed bosses symmetrically installed on the left side and the right side of a crusher Fang Guan, hydraulic push rods are fixedly installed on the fixed bosses, and movable slide rods are movably installed on the left side wall and the right side wall of the crushing square tank. According to the utility model, the extrusion crushing mechanism is arranged, and the sensor probe can be automatically extruded and crushed by utilizing the mutual matching between the extrusion square plate and the inclined straight plate, so that the nonmetallic framework in the sensor probe is separated from the coil, and then the framework fragments are screened by utilizing the blanking through holes, thereby helping workers to quickly complete coil recovery and greatly improving the coil recovery efficiency.

Description

Vibration sensor coil recovery device

Technical Field

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

Background

The electric vortex sensor system consists of a sensor probe, a shell, a front-end processor, a cable and a connector, wherein the sensor probe is a part of a sensor for sensing a detected signal and consists of a rectangular section coil wound on a nonmetal framework, and when the waste sensor probe is recovered, people usually separate the coil from the nonmetal framework and then recover the coil respectively because the recovery value of the metal coil is greatly different from the recovery value of the nonmetal framework.

In the prior art, when separating coil and nonmetallic skeleton, directly cut the coil generally, then peel off the coil from nonmetallic skeleton again, this not only can lead to recovery efficiency lower, cuts the cross-section that the coil formed and all has sharp-pointed burr in addition, causes the damage to staff's arm very easily, and the security is lower.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides the vibration sensor coil recovery device, solves the technical problems of low efficiency and safety in the process of separating the coil from the framework in the prior art, and has the advantages of capability of automatically crushing and separating the coil from the framework, no need of manual operation of staff, high safety and the like.

In order to solve the technical problems, the utility model provides the following technical scheme: the utility model provides a vibration sensor coil recovery unit, including receiving the material underframe, fixed mounting has broken side jar on the material underframe, the feeding breach has been seted up to the upper end of broken side jar, be provided with the crushing mechanism of extrusion on the broken side jar, the top of receiving the material underframe is provided with the piece and cleans the mechanism, the staff puts into the inside back of broken side jar with the sensor probe from the feeding breach, at first the crushing mechanism of extrusion can extrude the breakage to the sensor probe, make nonmetallic frame broken, later, the piece cleans the mechanism and can separate skeleton piece and coil, thereby accomplish the individual recovery to the coil, the fixed mounting has hydraulic push rod on the fixed boss including the fixed boss of symmetry installation in broken Fang Guan left and right sides, equal movable mounting has the movable slide bar on the left and right sides wall of broken side jar, the tip of movable slide bar extends to the inside of broken side jar and fixed mounting has the extrusion square board, the surface of extrusion square board is provided with broken sand grip, the lower extreme rotation of broken side jar inner chamber is connected with the slope straight board, rectangular square groove has been seted up to the sensor probe on the inside symmetry of material underframe, the inside square groove is provided with the slope straight board, the inside slope through-hole that the inside the slope spring that runs through the inside the blanking square groove is provided with the slope, can fall the through the metal through-hole to the piece, can fall down the through the metal through-hole to the slope directly to the coil from the inside piece, can fall down the slope to the inside the piece.

Preferably, the movable slide bar is connected with the hydraulic push rod in a transmission way, a plurality of crushing convex strips are arranged at equal intervals, and when the extrusion square plate moves horizontally under the action of the hydraulic push rod, the sensor probe is extruded and crushed.

Preferably, the front side and the rear side of the lower end of the inclined straight plate are fixedly provided with sliding convex blocks, the sliding convex blocks are in sliding connection with the rectangular square grooves, one end of the reset spring is fixedly connected with the rectangular square grooves, and the other end of the reset spring is in contact with the sliding convex blocks.

Preferably, the piece cleans mechanism and includes the mount pad of demountable installation at fixed boss lower extreme, and the movable mounting of mount pad has rotatory circle axle, and the outside of rotatory circle axle is provided with fixed branch, and fixed branch's tip is provided with the carding assembly, and the drive cavity has been seted up to the inside of mount pad, and the inside of drive cavity is provided with drive assembly, and rotatory circle axle can make the upper surface contact of carding assembly and slope straight board when drive assembly's effect rotates to separate piece and coil that will pile up together, make the piece can follow blanking through-hole and drop downwards.

Preferably, the carding assembly comprises a carding plate detachably mounted at the end part of the fixed supporting rod, a plurality of columnar convex teeth are arranged on the carding plate at equal intervals, and when the rotary round shaft rotates, the columnar convex teeth intermittently contact with the inclined straight plate, so that the inclined straight plate is in a shaking state, and the blanking is convenient.

Preferably, the driving assembly comprises a driving belt wheel movably mounted in the driving cavity, a transmission belt is arranged between the driving belt wheel and the rotary round shaft, a driving motor used for enabling the driving belt wheel to rotate is fixedly mounted outside the mounting seat, the rotary round shaft can be enabled to rotate through cooperation with the transmission belt when the driving belt wheel rotates, and a plurality of fixing support rods can be enabled to synchronously rotate when the rotary round shaft rotates.

By means of the technical scheme, the utility model provides a vibration sensor coil recovery device, which has at least the following beneficial effects:

1. according to the utility model, the extrusion crushing mechanism is arranged, the sensor probe can be automatically extruded and crushed by utilizing the mutual matching between the extrusion square plate and the inclined straight plate, so that the nonmetallic framework in the sensor probe is separated from the coil, and then the framework fragments are screened by utilizing the blanking through holes, thereby helping workers to quickly complete coil recovery, greatly improving the coil recovery efficiency, avoiding any damage to the workers and having high safety.

2. According to the utility model, the chip cleaning mechanism is arranged, and the chips piled on the inclined straight plate can be automatically spread by utilizing the mutual matching between the rotary circular shaft and the carding assembly, so that skeleton chips mixed in the coil fall from the blanking through holes, the chip screening effect can be effectively improved, and the inclined straight plate can be in a shaking state due to intermittent contact of the carding assembly and the inclined straight plate, so that the blanking is facilitated.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiments of the application and together with the description serve to explain the application and do not constitute an undue limitation to the application. In the drawings:

FIG. 1 is a front view of the overall structure of the present utility model;

FIG. 2 is a schematic diagram of a portion of the structure of the present utility model;

FIG. 3 is an internal schematic view of the debris sweeping mechanism of the present utility model;

fig. 4 is an internal schematic view of the mounting base of the present utility model.

In the figure: 1. a receiving bottom box; 2. crushing a square tank; 3. a feeding notch; 4. an extrusion crushing mechanism; 401. a fixing boss; 402. a hydraulic push rod; 403. a movable slide bar; 404. extruding the square plate; 405. crushing the convex strips; 406. tilting the straight plate; 407. rectangular square grooves; 408. a return spring; 409. blanking through holes; 5. a debris cleaning mechanism; 501. a mounting base; 502. rotating the circular shaft; 503. fixing the support rod; 504. a carding assembly; 505. a drive cavity; 506. and a drive assembly.

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.

Example 1

According to the embodiments shown in fig. 1-4, a vibration sensor coil recycling device comprises a receiving bottom box 1, wherein a crushing square tank 2 is fixedly installed on the receiving bottom box 1, a feeding gap 3 is formed in the upper end of the crushing square tank 2, an extrusion crushing mechanism 4 is arranged on the crushing square tank 2, a chip cleaning mechanism 5 is arranged above the receiving bottom box 1, a worker puts a sensor probe into the crushing square tank 2 from the feeding gap 3, and then the extrusion crushing mechanism 4 firstly performs extrusion crushing on the sensor probe to crush a nonmetallic skeleton, and then the chip cleaning mechanism 5 separates skeleton fragments from coils, so that independent recycling of the coils is completed.

Specifically, extrusion crushing mechanism 4 includes the fixed boss 401 of symmetry installation in the left and right sides of broken side jar 2, fixed mounting has hydraulic ram 402 on the fixed boss 401, equal movable mounting has movable slide bar 403 on the left and right sides wall of broken side jar 2, movable slide bar 403 is connected with hydraulic ram 402 transmission, the tip of movable slide bar 403 extends to the inside of broken side jar 2 and fixed mounting has extrusion square board 404, the surface of extrusion square board 404 is provided with broken sand grip 405, broken sand grip 405 equidistant is provided with a plurality of, when extrusion square board 404 moves under hydraulic ram 402's effect horizontal migration, can extrude the breakage to the sensor probe, the lower extreme rotation of broken side jar 2 inner chamber is connected with slope straight board 406, equal fixed mounting of front and back both sides of slope straight board 406 lower extreme has the slip lug, symmetrically seted up rectangular square groove 407 on the inside wall of material receiving bottom box 1, sliding connection between slip lug and the rectangular square groove 407, the inside of rectangular square groove 407 is provided with reset spring 408, reset spring 408's one end and rectangular square groove fixed connection, reset spring 408's the other end and the slip lug, the slope straight board 406 is provided with the through-hole 409 to the slope straight board 406, can realize falling down to the coil 409 along the inside slope through-hole that can not fall down to the through-hole along the slope piece, the inside the slope piece, can realize the slope piece is along the slope through-going up to the slope piece 406.

Specifically, the debris sweeping mechanism 5 includes a mounting seat 501 detachably mounted at the lower end of the fixing boss 401, a rotary round shaft 502 is movably mounted on the mounting seat 501, a fixing support rod 503 is arranged outside the rotary round shaft 502, a carding assembly 504 is arranged at the end of the fixing support rod 503, a driving cavity 505 is formed in the mounting seat 501, a driving assembly 506 is arranged in the driving cavity 505, and the carding assembly 504 is contacted with the upper surface of the inclined straight plate 406 when the rotary round shaft 502 rotates under the action of the driving assembly 506, so that the piled debris and coils are separated, and the debris can drop downwards from the blanking through hole 409.

More specifically, the carding assembly 504 includes a carding plate detachably mounted at the end of the fixing support rod 503, and a plurality of columnar protruding teeth are provided on the carding plate at equal intervals, so that when the rotary round shaft 502 rotates, the plurality of columnar protruding teeth intermittently contact with the inclined straight plate 406, and the inclined straight plate 406 is in a shaking state, so that blanking is facilitated.

More specifically, the driving assembly 506 includes a driving pulley movably mounted in the driving cavity 505, a transmission belt is disposed between the driving pulley and the rotating shaft 502, a driving motor for rotating the driving pulley is fixedly mounted outside the mounting seat 501, when the driving pulley rotates, the rotating shaft 502 rotates through cooperation with the transmission belt, and when the rotating shaft 502 rotates, the plurality of fixing struts 503 synchronously rotate.

In this embodiment, during the use, the staff can switch on the power of the device earlier, then will put the sensor probe that will handle into the inside of feeding breach 3 again, after the power switch-on, the horizontal direction reciprocating motion of activity slide bar 403 under the effect of hydraulic push rod 402, the direction of movement of two activity slide bars 403 is opposite throughout, can make extrusion square plate 404 synchronous movement when activity slide bar 403 removes, because the broken sand grip 405 on two extrusion square plates 404 crisscross setting each other, consequently, extrusion square plate 404 removes the in-process and can be continuous to the sensor probe and extrude broken.

The broken sensor probe then falls onto the inclined straight plate 406 and slides down the inclined straight plate 406, during which the broken nonmetallic fragments fall into the interior of the receiving hopper 1 through the blanking through holes 409, and the coil slides straight to the lower end of the inclined straight plate 406, thereby separating the sensor coil from the fragments.

At this time, the driving belt wheel rotates under the action of the driving motor, the rotating circular shaft 502 rotates synchronously through cooperation with the driving belt, and the fixing support rods 503 rotate synchronously when the rotating circular shaft 502 rotates, so that the plurality of carding assemblies 504 intermittently contact with the inclined straight plates 406.

In the contact process, firstly, the columnar convex teeth can spread nonmetallic fragments accumulated in one coil, so that fragments mixed in the coil drop downwards, the effect of separating the fragments is greatly improved, and moreover, the carding plate and the inclined straight plate 406 are intermittently contacted, so that the inclined straight plate 406 is in a shaking state all the time, and the blanking is convenient.

According to the embodiment, the extrusion crushing mechanism 4 is arranged, the sensor probe can be automatically extruded and crushed by utilizing the mutual matching between the extrusion square plate 404 and the inclined straight plate 406, so that a nonmetallic framework in the sensor probe is separated from a coil, and then framework fragments are screened by utilizing the blanking through holes 409, thereby helping workers to quickly complete coil recovery and greatly improving the coil recovery efficiency; in addition, this embodiment utilizes the mutual cooperation between rotatory circle axle 502 and the carding component 504 through setting up piece cleaning mechanism 5, can be automatically with piling up the piece on the straight board 406 of slope and spread out, makes the skeleton piece that is mingled with in the coil inside drop from blanking through-hole 409, can effectively improve the effect that the piece sieved, and moreover, carding component 504 and the straight board 406 intermittent type nature contact of slope can make the straight board 406 of slope be in and rock the state, the unloading of being convenient for.

The control mode of the utility model is automatically controlled by the controller, the control circuit of the controller can be realized by simple programming of a person skilled in the art, the supply of power also belongs to common knowledge in the art, and the utility model is mainly used for protecting a mechanical device, so the utility model does not explain the control mode and circuit connection in detail.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a vibration sensor coil recovery unit, includes material receiving bottom box (1), and fixed mounting has broken side jar (2) on material receiving bottom box (1), and feeding breach (3), its characterized in that have been seted up to the upper end of broken side jar (2): an extrusion crushing mechanism (4) is arranged on the crushing square tank (2), and a fragment cleaning mechanism (5) is arranged above the receiving bottom box (1);

the extrusion crushing mechanism (4) comprises fixing bosses (401) symmetrically arranged on the left side and the right side of the crushing square tank (2), hydraulic push rods (402) are fixedly arranged on the fixing bosses (401), movable slide bars (403) are movably arranged on the left side and the right side of the crushing square tank (2), the end parts of the movable slide bars (403) extend to the inside of the crushing square tank (2) and are fixedly provided with extrusion square plates (404), crushing convex strips (405) are arranged on the surfaces of the extrusion square plates (404), inclined straight plates (406) are connected to the lower ends of inner cavities of the crushing square tanks (2) in a rotating mode, rectangular square grooves (407) are symmetrically formed in the inner side walls of the material receiving bottom box (1), reset springs (408) are arranged in the rectangular square grooves (407), and blanking through holes (409) are formed in the surface penetrating mode of the inclined straight plates (406).

2. A vibration sensor coil recovery apparatus according to claim 1, wherein: the movable slide bar (403) is in transmission connection with the hydraulic push rod (402), and the crushing convex strips (405) are arranged in a plurality of at equal intervals.

3. A vibration sensor coil recovery apparatus according to claim 1, wherein: the front side and the rear side of the lower end of the inclined straight plate (406) are fixedly provided with sliding convex blocks, the sliding convex blocks are in sliding connection with the rectangular square grooves (407), one end of the return spring (408) is fixedly connected with the rectangular square grooves (407), and the other end of the return spring (408) is in contact with the sliding convex blocks.

4. A vibration sensor coil recovery apparatus according to claim 1, wherein: the debris cleaning mechanism (5) comprises a mounting seat (501) detachably mounted at the lower end of the fixing boss (401), a rotary round shaft (502) is movably mounted on the mounting seat (501), a fixing support rod (503) is arranged outside the rotary round shaft (502), a carding assembly (504) is arranged at the end part of the fixing support rod (503), a driving cavity (505) is formed in the mounting seat (501), and a driving assembly (506) is arranged in the driving cavity (505).

5. The vibration sensor coil recovery apparatus according to claim 4, wherein: the carding component (504) comprises a carding plate detachably arranged at the end part of the fixed supporting rod (503), and a plurality of columnar convex teeth are arranged on the carding plate at equal intervals.

6. The vibration sensor coil recovery apparatus according to claim 4, wherein: the driving assembly (506) comprises a driving belt wheel movably mounted in the driving cavity (505), a transmission belt is arranged between the driving belt wheel and the rotary round shaft (502), and a driving motor for enabling the driving belt wheel to rotate is fixedly mounted outside the mounting seat (501).