CN114811603A - Heavy hammer type bridge breaking device - Google Patents

Abstract

The invention relates to a heavy hammer type bridge breaking device which comprises a vertically arranged frame body, wherein the frame body is arranged on the inner side wall of a rear wall of a feed hopper, the lower end of the frame body is provided with a hammer head integrated with the frame body, the frame body is connected with the telescopic end of a breaking frame hydraulic cylinder, the breaking frame hydraulic cylinder is vertically arranged, the telescopic end of the breaking frame hydraulic cylinder faces downwards, the upper end of the breaking frame hydraulic cylinder is fixed on the end surface of the rear wall, the telescopic end of the breaking frame hydraulic cylinder is fixedly connected with the lower end of the interior of the frame body after the breaking frame hydraulic cylinder extends into the interior of the frame body, limiting plates are fixed on the rear walls on the left side and the right side of the frame body, the limiting plates are arranged in parallel to the rear wall, the corresponding end parts of the frame body are positioned between the limiting plates and the rear wall, and a second guide groove of the frame body is formed between the rear wall and the limiting plates. The garbage bridging device adopts a simple heavy hammer structure, and forcibly relieves garbage bridging through the up-and-down movement of the heavy hammer.

Description

Heavy hammer type bridge breaking device

Technical Field

The invention belongs to the technical field of household garbage incineration, and relates to a heavy hammer type bridge breaking device.

Background

The feeding system of the garbage incineration process is mainly used for receiving and storing garbage, and the stored garbage is continuously and safely conveyed to a fire grate to be incinerated through a reciprocating mechanism. The detailed structure comprises a feed hopper, a chute and a feeder (a feed trolley and a feed platform).

The feeding hopper adopts a trapezoidal funnel type structure, receives garbage grabbed by a grab bucket of a garbage crane, and ensures that the garbage can continuously slide into a chute of the feeding channel under the action of self weight through a specific inclination angle of a front wall of the hopper. The bottom of the feed hopper is connected with the chute, the chute is a straight pipe structure with a rectangular cross section, the size of the rectangular cross section of the chute is gradually increased from the top to the bottom to form a shape with a small top and a big bottom, and the garbage slides into the chute from the feed hopper to be stored to form a material column. The feeder is arranged below the chute and surrounded by a chute lower structure and comprises a feeding trolley and a feeding platform, the garbage stored in the chute is piled up from the feeding platform, and the feeding trolley reciprocates on the feeding platform to push the garbage on the feeding platform into the incinerator.

The feeding hopper, the chute and the feeding platform are connected to form a feeding channel, and the minimum position in the whole feeding channel is the connecting position of the bottom of the feeding hopper and the chute. On the one hand, rubbish slides in from the feeder hopper, reaches the feeding platform through the chute, and rubbish only relies on the dead weight effect, except the feeding dolly reciprocating motion of bottom, whole process does not have other external force drives. On the other hand, except for the fermentation step, the garbage is not pretreated, and the condition that the size of the garbage is too large and the garbage is densely accumulated may cause the connection position between the bottom of the garbage feeding hopper and the chute to be bridged.

After the bridge, the rubbish of feeder hopper can't slide down through self action of gravity by oneself, along with constantly pushing of feed dolly, can push away the rubbish of bridge position below empty, and lead to the feed platform top to have empty local temperature to be super high, this hollow peripheral rubbish can catch fire, and in the serious time, the rubbish combustion face that cavity department caused enlarges, the rubbish sintering on the whole feed platform can appear, lead to all feed dollies not to push away the rubbish of sintering, the unable continuous feeding of whole stove.

Disclosure of Invention

In view of the above, the present invention provides a heavy hammer type bridging breaking device for solving the problem that the continuous feeding is affected after the garbage bridging at the bottom of the feeding hopper, and the device can perform a strong releasing of the garbage bridging before the feeding platform does not push out the cavity or the garbage at the cavity is not combusted, so as to ensure that the garbage continuously enters the chute and the feeding platform.

In order to achieve the purpose, the invention provides the following technical scheme:

the utility model provides a broken bridging device of weight formula, frame including vertical setting, the frame sets up on the back wall inside wall of feeder hopper, the lower extreme of frame is provided with rather than integrative tup, the frame is connected with the flexible end of broken frame pneumatic cylinder, broken vertical setting of frame pneumatic cylinder and flexible end are down, the upper end of broken frame pneumatic cylinder is fixed on the back wall up end, its flexible end concreties with the inside lower extreme of frame after broken frame pneumatic cylinder stretches into the inside of frame, be fixed with the limiting plate on the back wall of the frame left and right sides, limiting plate and back wall parallel arrangement, the tip that the frame corresponds is located between limiting plate and the back wall, form guide way two of frame between back wall and the limiting plate.

Furthermore, a pair of guide wheels positioned on the same horizontal line are respectively fixed on the upper parts of the left side wall and the right side wall of the frame body, and the two guide wheels are respectively contacted with the rear wall and the limiting plate to realize rolling friction.

Furthermore, a second cover plate is arranged on the outer side wall of the frame body and corresponds to the guide wheel, and the second cover plate can be detached.

Furthermore, the hammer head is of a triangular structure with the pointed end facing downwards.

Furthermore, the end part of the first hydraulic cylinder support extends out of the outer side of the rear wall and is hinged with the frame breaking hydraulic cylinder.

Furthermore, a detachable cover plate I is arranged on the outer side of the frame body at the frame breaking hydraulic cylinder.

The invention has the beneficial effects that:

the invention can effectively solve the problem of garbage bridging in the feed hopper and the chute, adopts a simple heavy hammer structure, forcibly removes the garbage bridging through the up-and-down movement of the heavy hammer, and has convenient operation and strong practicability.

Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention. The objectives and other advantages of the invention may be realized and attained by the means of the instrumentalities and combinations particularly pointed out hereinafter.

Drawings

For the purposes of promoting a better understanding of the objects, aspects and advantages of the invention, reference will now be made to the following detailed description taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic structural view of a waste incineration feeding system;

FIG. 2 is a schematic view of the feed hopper;

FIG. 3 is a front view of the bridge breaker mounted within the feed hopper;

FIG. 4 is a top view of the bridge breaker mounted within the feed hopper;

FIG. 5 is a schematic structural view of a bridge-breaking device and a locking device of the feed hopper;

FIG. 6 is a front view of the locking device;

FIG. 7 is a top view of the locking device;

FIG. 8 is a front view of the receptacle;

FIG. 9 is a top view of the socket;

FIG. 10 is a schematic view of the chute and the sealing and isolating device within the chute;

FIG. 11 is a cross-sectional view of the junction of the isolation door and the swing arm;

FIG. 12 is an enlarged view of the seal isolator;

FIG. 13 is an enlarged partial view at the rocker arm;

FIG. 14 is a partial enlarged view of the bottom connecting structure of the sealing cylinder;

FIG. 15 is a front view of the chute and seal isolation apparatus;

fig. 16 is a control system diagram of the present system.

Reference numerals:

100. a feed hopper; 110. a front wall; 120. a rear wall; 121. a guide strip; 122. a limiting plate; 123. a high level gauge; 200. a chute; 210. sealing the door space; 220. a low level indicator; 230. opening a switch; 240. closing the switch; 300. a feeder; 400. a bridge breaking device; 410. a frame body; 411. a hammer head; 412. a first guide groove; 413. a first cover plate; 414. a guide wheel; 415. a second cover plate; 416. locking; 417. the broken frame moves back to the position switch; 418. the broken frame enters a position switch; 420. a frame breaking hydraulic cylinder; 421. a first hydraulic cylinder support; 422. breaking a bridge and hydraulically driving a reversing valve; 500. a locking device; 510. a second support; 520. locking a hydraulic cylinder; 530. a lock head; 531. an induction sheet; 540. a socket; 541. a jack; 550. a switch mounting bracket; 551. mounting holes; 560. locking the in-position switch; 570. locking the return switch; 580. locking a hydraulic drive reversing valve; 600. sealing the isolation device; 610. an isolation gate; 620. a swing shaft; 630. a rocker arm; 640. sealing the hydraulic cylinder; 650. a sealed hydraulically driven reversing valve; 700. a protection plate; 800. and a controller.

Detailed Description

The embodiments of the present invention are described below with reference to specific embodiments, and other advantages and effects of the present invention will be easily understood by those skilled in the art from the disclosure of the present specification. The invention is capable of other and different embodiments and of being practiced or of being carried out in various ways, and its several details are capable of modification in various respects, all without departing from the spirit and scope of the present invention. It should be noted that the drawings provided in the following embodiments are only for illustrating the basic idea of the present invention in a schematic way, and the features in the following embodiments and examples may be combined with each other without conflict.

Wherein the showings are for the purpose of illustrating the invention only and not for the purpose of limiting the same, and in which there is shown by way of illustration only and not in the drawings in which there is no intention to limit the invention thereto; to better illustrate the embodiments of the present invention, some parts of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

The same or similar reference numerals in the drawings of the embodiments of the present invention correspond to the same or similar components; in the description of the present invention, it should be understood that if there is an orientation or positional relationship indicated by terms such as "upper", "lower", "left", "right", "front", "rear", etc., based on the orientation or positional relationship shown in the drawings, it is only for convenience of description and simplification of description, but it is not an indication or suggestion that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore, the terms describing the positional relationship in the drawings are only used for illustrative purposes, and are not to be construed as limiting the present invention, and the specific meaning of the terms may be understood by those skilled in the art according to specific situations.

Referring to fig. 1 to 16, a feeding system for waste incineration sequentially comprises a feeding hopper 100, a chute 200 and a feeder 300 from top to bottom, wherein the feeding hopper 100 is of an inverted bell mouth structure and has a large top and a small bottom, the chute 200 is a rectangular tube, and the upper end of the chute 200 is fixedly connected with the bottom of the feeding hopper 100 through a flange. The chute 200 is divided into an upper section and a lower section, and the chute 200 is fixedly connected with each other through an expansion joint. The feeder 300 includes a feeding platform and a feeding trolley above the feeding platform, the feeding trolley is located at the outlet of the chute 200, the feeding trolley reciprocates on the feeding platform, and the feeding trolley continuously and safely conveys the garbage falling from the chute 200 to a fire grate for incineration. The feed car is controlled by the controller 800.

The feeding hopper 100 includes a front wall 110 and a rear wall 120, the front wall 110 being a slant surface, and the rear wall 120 being a vertical surface. The inner side wall of the rear wall 120 is provided with a bridging device 400, and the bridging device 400 can break the bridge between the feed hopper 100 and the chute 200.

The frame breaking and bridging device 400 comprises a vertically arranged frame body 410, the frame body 410 is of a rectangular frame structure, the lower end of the frame body 410 is provided with a hammer head 411 integrated with the frame body, and in order to guarantee the frame breaking effect, the hammer head 411 is of a triangular structure with the tip end facing downwards. The frame body 410 is connected with the telescopic end of the frame breaking hydraulic cylinder 420, and the frame breaking hydraulic cylinder 420 drives the frame body 410 to realize up-and-down reciprocating motion, so that a bridge breaking effect is realized. The frame breaking hydraulic cylinder 420 is vertically arranged, the telescopic end of the frame breaking hydraulic cylinder 420 faces downwards, the upper end of the frame breaking hydraulic cylinder 420 is fixed to the first hydraulic cylinder support 421, the first hydraulic cylinder support 421 is fixed to the upper end face of the rear wall 120, and the end of the first hydraulic cylinder support 421 extends out of the outer side of the rear wall 120 and then is hinged to the frame breaking hydraulic cylinder 420. The frame breaking hydraulic cylinder 420 extends into the frame body 410 and then the telescopic end thereof is fixedly connected with the lower end of the interior of the frame body 410. The frame breaking hydraulic cylinder 420 is connected with the controller 800.

The preferred breaking hydraulic cylinders 420 are provided in a pair, and the breaking hydraulic cylinders 420 are symmetrically provided with respect to the center line of the frame body 410.

In order to prevent the frame body 410 from swinging left and right, the side wall of the frame body 410 opposite to the rear wall 120 is provided with a first vertically extending guide groove 412, the corresponding rear wall 120 is fixed with a guide strip 121 matched with the first guide groove 412, the guide strip 121 is also vertically arranged, preferably, the first guide groove 412 is provided with a pair and is symmetrically arranged relative to the central line of the frame body 410, and the same guide strip 121 is also provided with a pair.

The outer side of the frame body 410 provided with the broken frame hydraulic cylinder 420 is provided with a detachable cover plate I413, and the cover plate I413 can be opened for operation when the broken frame hydraulic cylinder 420 is installed or overhauled.

In order to prevent the upper end of the frame body 410 from being inclined, a limiting plate 122 is fixed to the rear wall 120 on the left and right sides of the frame body 410, the limiting plate 122 is disposed parallel to the rear wall 120, the corresponding end of the frame body 410 is located between the limiting plate 122 and the rear wall 120, and a second guide groove of the frame body 410 is formed between the rear wall 120 and the limiting plate 122. In order to reduce the friction force of the vertical movement of the frame body 410, a pair of guide wheels 414 located on the same horizontal line are respectively fixed on the upper portions of the left and right side walls of the frame body 410, and the two guide wheels 414 are respectively in contact with the rear wall 120 and the limiting plate 122 to realize rolling friction. In order to facilitate the installation and maintenance of the guide wheel 414, a second cover plate 415 is arranged on the outer side wall of the frame body 410 at a position corresponding to the guide wheel 414, the second cover plate 415 can be detached, and the installation and maintenance of the guide wheel 414 are realized at the second cover plate 415.

When the bridge is released or no bridge is formed, the bridge breaking device 400 needs to be pulled to the highest point by the bridge breaking hydraulic cylinder 420, so that feeding of the feeding hopper 100 is not affected, at this time, a vertical downward acting force always exists on the bridge breaking device 400 under the action of gravity, and the bridge breaking hydraulic cylinder 420 correspondingly has an upward pulling force to keep the bridge breaking device balanced and not fall. However, it is difficult to maintain the pressure and maintain the tension of the frame-breaking hydraulic cylinder 420 for a long time, and the frame-breaking device 400 falls down due to gravity because the upward tension is reduced due to natural pressure relief inside the frame-breaking hydraulic cylinder 420. Therefore, to solve the problem that the feeding hopper 100 is affected by the natural falling of the bridging device 400 when the bridging device 400 is not in operation, a locking device 500 needs to be designed to fix the bridging device 400 at the highest position of the feeding hopper 100.

The locking device 500 is provided on the upper end surface of the rear wall 120 at the center line position of the frame body 410. The locking device 500 comprises a second support base 510, a locking hydraulic cylinder 520 horizontally placed is arranged on the second support base 510, and the locking hydraulic cylinder 520 is electrically connected with the controller 800. The telescopic end of the locking hydraulic cylinder 520 faces the bridge breaking device 400 and is perpendicular to the frame body 410 of the bridge breaking device 400, and the telescopic end of the locking hydraulic cylinder 520 is fixedly connected with a long-strip-shaped lock head 530. One end of the lock head 530 is hinged with the telescopic end of the locking hydraulic cylinder 520 through a pin shaft. A socket 540 is fixed on the second support 510 close to the bridging device 400, a jack 541 which is matched with the lock 530 and penetrates through the socket 540 is arranged in the middle of the socket 540, and the lock 530 can penetrate through the jack 541 and reciprocate in the jack 541.

A lock catch 416 matched with the lock head 530 is fixed in the middle of the upper end surface of the frame body 410 of the corresponding bridge-breaking device 400. The cross-section of the lock catch 416 is an inverted L-shaped structure that opens toward the lock head 530. The locking head 530 can be inserted into the lock catch 416. To facilitate insertion of the locking head 530 into the catch 416, the upper edge of the free end of the locking head 530 is chamfered.

A switch mounting rack 550 is fixed on a second support 510 at the side of the socket 540, mounting holes 551 distributed front and back are formed in the switch mounting rack 550, the mounting holes 551 are horizontal long round mounting holes, the two mounting holes 551 are on the same horizontal line, a locking in-position switch 560 and a locking out-position switch 570 are respectively fixed in the mounting holes 551, the locking in-position switch 560 and the locking out-position switch 570 are respectively position sensors, a sensing piece 531 matched with the locking in-position switch 560 and the locking out-position switch 570 is fixed on the lock head 530, when the sensing piece 531 reaches the locking in-position switch 560, the locking hydraulic cylinder 520 stops extending, and when the sensing piece 531 reaches the locking out-position switch 570, the locking hydraulic cylinder 520 stops retracting. The lock-in bit switch 560 and the lock-out bit switch 570 are electrically connected to the controller 800, respectively.

The locking in-position switch 560 can limit the insertion of the lock head 530 into the lock catch 416, and the locking requirement is met. The locking in-place switch 570 requires the locking head 530 to completely withdraw from the locking buckle 416 without causing interference to the operation of the bridge-breaking device 400.

An arc-shaped protection plate 700 is fixed above the locking device 500 and the first hydraulic cylinder support 421, and the protection plate 700 is used for preventing impurities such as garbage and dust from entering the locking device 500 and the first hydraulic cylinder support 421.

The sealing and isolating device 600 is arranged at the joint of the feed hopper 100 and the chute 200, and the sealing and isolating device 600 is used for realizing the isolation of the inside and the outside of the incinerator when the household garbage incinerator is started and stopped and does not receive garbage.

The seal isolation device 600 includes a rotatable isolation door 610, the isolation door 610 is located within the chute 200 at the junction of the feed hopper 100 and the chute 200, and the isolation door 610 may completely cover the junction of the feed hopper 100 and the chute 200. The rear end of the isolating door 610 is fixed on the swinging shaft 620, two ends of the swinging shaft 620 penetrate out of the chute 200 respectively and then are fixedly connected with one end of the swinging arm 630, the other end of the swinging arm 630 is hinged with the telescopic end of the sealing hydraulic cylinder 640, the base of the sealing hydraulic cylinder 640 is fixed on the side wall of the chute 200 through the fixing seat, and the base of the sealing hydraulic cylinder 640 is hinged with the fixing seat. The extension and contraction of the sealing hydraulic cylinder 640 drives the rocker arm 630 to rotate, and the swinging angle just accords with the opening angle of the sealing door. The sealing cylinder 640 is connected to the controller 800.

The junction of the swing shaft 620 and the chute 200 is sealed by shaft end seal plates and seal strips.

The inside rear side of chute 200 is provided with sealing door space 210 that is used for holding the sealing door, and when the sealing door was opened completely, the sealing door guaranteed falling smoothly of rubbish in a vertical plane with the rear side wall of chute 200.

If the chute 200 is long, a plurality of isolation doors 610 can be arranged to be connected in the middle, and the joints of the isolation doors 610 and the isolation doors 610 are sealed by fixing sealing strips. The connection between the isolation door 610 and the swing shaft 620 of the isolation door 610 is fixedly connected by a fixed connection.

The sealing isolation door 610 is provided with an isolation door limiting device, and the corresponding positions on the side wall of the chute 200 are respectively provided with a sealing in-position switch and a sealing out-position switch. The sensing blocks matched with the seal in-position switch and the seal out-position switch are arranged on the rocker arm 630 and rotate along with the extension and contraction of the seal hydraulic cylinder 640 together with the rocker arm 630. When the rocker arm 630 and the sensing block rotate to the position of the seal in-place switch or the seal back-to-place switch, the switch outputs a carry signal or a back-to-place signal to the controller 800, the controller 800 stops supplying oil, and the seal hydraulic cylinder 640 stops acting, so that the isolation door 610 keeps an open state or a closed state.

In order to realize the automatic control of the system, a fixed high level indicator 123 is arranged at a position close to the lower end of the feeding hopper 100, the high level indicator 123 is connected with the controller 800, the high level indicator 123 detects feeding, and when the garbage storage position reaches the position, a high level material signal is output to remind that external incoming materials can be stopped to enter the feeding hopper 100. Otherwise, when the stored garbage falls to be lower than the high material level, a high material level material-free signal is output, and the high material level material-free is displayed.

Meanwhile, a low level indicator 220 is arranged at the middle position inside the chute 200 connected with the feed hopper 100, the low level indicator 220 is connected with the controller 800, when the garbage storage position falls below the position, a low level material-free signal is output, and the alarm is given out to supplement fuel as soon as possible. Otherwise, when the stored garbage is higher than the low material level, a low material level material signal is output, and the low material level material is displayed.

The frame breaking and bridging device 400 is provided with a frame breaking and returning position switch 417 which is fixed at the upper end of the rear wall 120 of the feed hopper 100 and is connected with the controller 800, the frame breaking and bridging device 400 is mainly detected to return to the position by the frame breaking and bridging device 417 serving as an initial position of the frame breaking and bridging device 400, a signal is output to the controller 800 after the frame breaking and bridging device 400 returns to the position, and the controller 800 controls the frame breaking hydraulic cylinder 420 to stop oil supply. The frame breaking hydraulic cylinder 420 is also connected with a bridge breaking hydraulic drive reversing valve 422, and the bridge breaking hydraulic drive reversing valve 422 is connected with the controller 800.

The rack-breaking and bridging device 400 is provided with a rack-breaking and bridging-in switch 418, which is fixed in the middle of the rear wall 120 of the feed hopper 100 and mainly detects whether the rack-breaking and bridging device 400 is in place, and the rack-breaking and bridging-in switch 418 is electrically connected with the controller 800. After the frame-breaking bridge-erecting device 400 is in place, the frame-breaking frame-entering position switch 418 outputs a signal to the controller 800, and the controller 800 controls the frame-breaking hydraulic cylinder 420 to stop advancing oil supply.

The locking hydraulic cylinder 520 is connected to a locking hydraulically actuated directional control valve 580, and the locking hydraulically actuated directional control valve 580 is electrically connected to the controller 800. The locking hydraulic drive reversing valve 580, as the controller 800, receives that the locking device 500 is moved to the right position or moved back to the right position to stop the locking hydraulic cylinder 520 from supplying oil, the direction of the supplied oil is changed, the oil is supplied in the forward direction originally, and the oil is supplied in the backward direction after the direction is changed, or vice versa.

The isolation door 610 of the sealing isolation device 600 is provided with an opening switch 230 and a closing switch 240, and the opening switch 230 and the closing switch 240 are electrically connected to the controller 800. The sealed hydraulic cylinder 640 is also connected to a sealed hydraulically actuated directional valve 650, and the sealed hydraulically actuated directional valve 650 is electrically connected to the controller 800.

The opening switch 230 is used as an initial position of the isolation door 610, mainly detects that the isolation door 610 completely opens the connection channel between the feed hopper 100 and the chute 200, and outputs a signal (an opening signal of the isolation door 610) to the controller 800 to stop the oil supply of the sealing hydraulic cylinder 640.

The switch 240 is closed, the isolation door 610 is mainly detected to completely close the connection passage between the feed hopper 100 and the chute 200, and a signal (the isolation door 610 closing signal) is output to the controller 800 to stop the oil supply of the sealing hydraulic cylinder 640.

The sealing hydraulic drive reversing valve 650, as a hydraulic system, receives that the isolation door 610 is completely opened or closed, and after stopping oil supply, the direction of oil supply is changed, which is originally forward oil supply, and is backward oil supply after changing the direction, or vice versa.

The working principle of the invention is as follows:

whether the feed hopper 100 and the chute 200 are bridged or not is judged, and two conditions exist.

Firstly, the isolation door 610 is opened, and when the low level indicator 220 detects a material signal, the feed hopper 100 is not bridged; when the low level indicator 220 detects no material and the high level indicator 123 detects material, the bridge is judged to be a bridge, which is called a bridge signal; when the low level indicator 220 detects no material and the high level indicator 123 detects no material, alarming for feeding is needed.

Secondly, the isolation door 610 is closed, and when the low level indicator 220 detects no material and the high level indicator 123 detects material, the bridge cannot be determined.

Can be simply described as: the isolation gate 610 opens a signal + the low level indicator 220 has no material signal + the high level indicator 123 has a material signal, i.e., a bridging signal. The low level indicator 220 has a material signal and the bridging signal is removed.

A control method for starting a broken bridge.

First, if a bridging signal occurs, and at this time, there are a signal indicating that the bridging device 400 has retreated to the position and a signal indicating that the locking device 500 has advanced to the position, the locking device 500 needs to be first activated to unlock until the signal indicating that the locking device 500 has retreated to the position occurs.

Can be simply described as: the bridging signal + the bridge breaking device 400 retreats to the bit signal + the locking device 500 enters the bit signal, and the locking device 500 is started to unlock.

Secondly, when the locking device 500 enters the position signal and the sealing door opening signal exists, the bridging breaking device 400 starts to move downwards and inserts and extrudes the garbage at the bridging position until the bridging breaking device 400 enters the position signal, starts to retreat, and retreats to the position signal until the bridging breaking device 400 retreats, starts to advance again and again until the bridging signal is relieved.

Can be simply described as: the bridging signal, the locking device 500 retreating to the position signal and the sealing door opening signal, and the bridging breaking device 400 starts the bridge breaking until the bridging signal is removed.

Thirdly, after the bridging signal is released and the bridging breaking device 400 is withdrawn to the right position, the locking device 500 advances until the locking device 500 reaches the right position, and the surface bridging breaking device 400 is locked.

Can be simply described as: the non-bridging signal + the bridging device 400 retreats to the position signal, and the locking device 500 advances to lock the bridging device 400.

The seal separator 600 is closed requiring receipt of a lock 500 in-place signal.

In addition to automatic detection, a manually activated bridge-breaking device 400 may be provided in the event that the seal-isolating device 600 is opened.

Finally, the above embodiments are only intended to illustrate the technical solutions of the present invention and not to limit the present invention, and although the present invention has been described in detail with reference to the preferred embodiments, it will be understood by those skilled in the art that modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions, and all of them should be covered by the claims of the present invention.

Claims (6)

1. The utility model provides a broken bridging device of weight formula which characterized in that: comprises a vertically arranged frame body (410), the frame body (410) is arranged on the inner side wall of the rear wall (120) of the feed hopper (100), the lower end of the frame body (410) is provided with a hammer head (411) integrated with the frame body, the frame body (410) is connected with the telescopic end of a frame breaking hydraulic cylinder (420), the frame breaking hydraulic cylinder (420) is vertically arranged with the telescopic end facing downwards, the upper end of the frame breaking hydraulic cylinder (420) is fixed on the upper end surface of the rear wall (120), the telescopic end of the frame breaking hydraulic cylinder (420) is fixedly connected with the lower end of the interior of the frame body (410) after extending into the interior of the frame body (410), the limiting plates (122) are fixed on the rear walls (120) on the left side and the right side of the frame body (410), the limiting plates (122) are arranged in parallel with the rear walls (120), the corresponding end parts of the frame body (410) are located between the limiting plates (122) and the rear walls (120), and a second guide groove of the frame body (410) is formed between the rear walls (120) and the limiting plates (122).

2. The weight hammer type bridge-breaking device according to claim 1, wherein: a pair of guide wheels (414) positioned on the same horizontal line is respectively fixed on the upper parts of the left side wall and the right side wall of the frame body (410), and the two guide wheels (414) are respectively contacted with the rear wall (120) and the limiting plate (122) to realize rolling friction.

3. The weight hammer type bridge-breaking device according to claim 2, wherein: and a second cover plate (415) is arranged on the outer side wall of the frame body (410) at a position corresponding to the guide wheel (414), and the second cover plate (415) can be detached.

4. The weight hammer type bridge-breaking device according to claim 1, wherein: the hammer head (411) is of a triangular structure with a downward tip.

5. The weight hammer type bridge-breaking device according to claim 1, wherein: the end part of the first hydraulic cylinder support (421) extends out of the outer side of the rear wall (120) and is hinged with the frame breaking hydraulic cylinder (420).

6. The weight hammer type bridge-breaking device according to claim 1, wherein: a detachable cover plate I (413) is arranged on the outer side of the frame body (410) at the frame breaking hydraulic cylinder (420).

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