CN112317080A - Multi-station sagger material breaking system - Google Patents

Abstract

The invention provides a multi-station sagger material breaking system, which comprises: a frame body; the material breaking stations are sequentially arranged in the rack body along the conveying direction; the material block breaking devices are arranged on the material block breaking stations in a one-to-one correspondence mode and used for conducting a plurality of times of block breaking processing operations on the materials along the conveying direction, conveying saggars which are fired in the kiln along the preset conveying direction in an automatic production system, sequentially conducting block breaking processing on the materials in the saggars in the conveying process, and ensuring that the materials in the saggars can be fully reduced into powder through a plurality of times of block breaking processing with different contact areas, and the whole process is achieved through automatic conveying, so that the block breaking efficiency and the automatic production efficiency are greatly improved; in addition, guarantee the leakproofness of whole broken piece processing operation through the frame body, avoid the dust to spill over and pollute the production environment and in time discharge the dust, improve the security of equipment operation.

Description

Multi-station sagger material breaking system

Technical Field

The invention belongs to the technical field of kiln production, and particularly relates to a multi-station sagger material breaking system.

Background

Due to the characteristic of high temperature of the kiln, powdery materials such as graphite powder and the like coming out from the kiln can be coagulated and solidified along with high-temperature drying, the coagulated materials in the subsequent working section can not meet the production requirement, and the phenomenon that the coagulated materials directly enter the subsequent working section greatly limits the production efficiency and the product yield for the subsequent working section. Therefore, a special material breaking device is needed to break and crush the agglomerated materials to reduce the agglomerated materials into powder. Before the broken block crushing treatment, the saggars burnt in the kiln are conveyed to a broken block treatment station through a conveying device. In the prior art, the saggars conveyed to the fragment processing station are directly subjected to fragment crushing treatment, so that the conveying device and even the saggars are easily damaged due to the pushing force in the fragment breaking process; the block breaking treatment mechanism usually adopts a mechanical driving structure to drive the blade to break and crush the agglomerated materials, so that the power is uncontrollable in the block breaking treatment process, and energy is wasted; in addition, the single broken block treatment causes the broken block to be insufficient, reduces the broken block treatment efficiency and is not beneficial to automatic production.

Disclosure of Invention

The present invention has been made to solve the above problems, and an object of the present invention is to provide a multi-station sagger material chunking system capable of sufficiently performing chunking processing on materials in saggars in an automated production system to improve chunking efficiency and production efficiency.

The invention provides a multi-station sagger material block breaking system, which is used for conveying saggers burnt in a kiln along a preset conveying direction and carrying out a plurality of times of block breaking treatment operations on the materials in the saggers, and is characterized by comprising the following steps: a frame body;

the material breaking stations are sequentially arranged in the rack body along the conveying direction;

and the material block breaking devices are arranged on the material block breaking stations in a one-to-one correspondence manner and are used for carrying out a plurality of times of block breaking processing operations on the materials along the conveying direction.

In the multi-station sagger material breaking system provided by the invention, the system can also be characterized in that each material breaking device comprises:

a sagger conveying device having a conveying path corresponding to the conveying direction and for conveying the sagger along, the conveying path having a hollow area formed thereon;

a sagger lifting device arranged below the hollow area and used for lifting the sagger conveyed to the hollow area to a preset height position so as to be separated from the sagger conveying device;

and the material block breaking device is arranged above the hollow area and used for carrying out block breaking treatment operation on the saggar supported by the saggar lifting device.

The multi-station sagger material breaking system provided by the invention can also be characterized in that the material breaking device comprises a blade assembly which has a preset contact area with the material and is used for breaking and crushing the material.

In the multi-station sagger material breaking system, the contact area of the blade assemblies is different when the plurality of material breaking devices are arranged.

In the multi-station sagger material block breaking system provided by the invention, the multi-station sagger material block breaking system can be further characterized in that the contact area of the blade assemblies of the plurality of material block breaking devices is set to be gradually increased along the conveying direction of the plurality of material block breaking devices.

In the multi-station sagger material breaking system provided by the invention, the system can be further characterized in that each material breaking device is also provided with a shell for fixedly sealing the sagger conveying device, the sagger lifting device and the material breaking device, the shell is provided with a first opening and a second opening on the opposite side walls along the conveying direction,

the frame body by the casing concatenation forms, adjacent two the casing first opening with the second opening is spliced fixedly mutually.

The multi-station sagger material breaking system provided by the invention can also be characterized in that the plurality of material breaking stations are respectively and correspondingly provided with a dust removal device, and the dust removal device is provided with a dust collection cover facing the sagger.

The multi-station sagger material block breaking system provided by the invention can also be characterized in that the dust collection covers corresponding to the plurality of material block breaking stations are communicated with the dust removal driving mechanism.

In the multi-station sagger material block breaking system provided by the invention, the system can also be characterized in that each dust hood is provided with a switch valve, and the size of the opening of the corresponding switch valve is adjusted according to the distance between the dust hood and the dust removal driving mechanism.

The multi-station sagger material block breaking system provided by the invention can also be characterized in that the rack body is of a hollow structure covering the plurality of material block breaking stations and the plurality of material block breaking devices, and an input port and an output port are formed in two opposite side walls of the rack body along the conveying direction.

The multi-station sagger material breaking system provided by the invention can also have the characteristics that the number of the material breaking stations is three, four or five, and the cross section of the corresponding blade assembly is in a cross shape, a rice shape or a grid shape.

Action and Effect of the invention

According to the multi-station sagger material block breaking system, in an automatic production system, saggers which are fired in a kiln are conveyed along a preset conveying direction, in the conveying process in a plurality of material block breaking stations, a plurality of material block breaking devices sequentially carry out block breaking treatment on the materials in the saggers, and the materials in the saggers can be fully reduced into powder through a plurality of times of block breaking treatments with different contact areas and different degrees, and the whole process is realized through automatic conveying, so that the block breaking efficiency and the automatic production efficiency are greatly improved; in addition, guarantee the leakproofness of whole broken piece processing operation through the frame body, avoid the dust to spill over and pollute the production environment, moreover, through dust exhaust mechanism in time discharge the dust, each device of frame body inside also can not damaged by the dust, improve equipment operation's security.

Drawings

Fig. 1 is a schematic structural diagram of a multi-station sagger material breaking system in an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a sagger material breaking device in an embodiment of the invention.

Fig. 3 is a schematic structural diagram of a housing in an embodiment of the invention.

Figure 4 is a front view of a plurality of dust cages in an embodiment of the invention.

FIG. 5 is a top view of a sagger conveyor in an embodiment of the present invention.

Fig. 6 is a side view of a sagger delivery device in an embodiment of the present invention.

Fig. 7 is a schematic structural view of a guide part in an embodiment of the present invention.

Fig. 8 is a front view of a sagger raising and lowering device in an embodiment of the present invention.

Fig. 9 is a side view of a sagger raising and lowering device in an embodiment of the present invention.

Fig. 10 is a front view of a material breaking device in an embodiment of the invention.

Fig. 11 is a side view of a material breaking apparatus in an embodiment of the invention.

Fig. 12 is a top view of a material breaking device in an embodiment of the invention.

Detailed Description

The invention is further illustrated by the following examples, which are not intended to limit the scope of the invention.

< example >

Because the powdery materials such as graphite powder in the sagger 200 are easy to agglomerate in the firing process in the kiln, and are not beneficial to subsequent automatic production, based on this, as shown in fig. 1 to 12, the embodiment discloses a multi-station sagger material agglomeration breaking system 1000, which can perform multiple agglomeration processing operations on the materials in the sagger 200, so that the materials in the sagger 200 are fully reduced into powder.

Specifically, as shown in fig. 1, the multi-station sagger material breaking system 1000 includes material breaking stations sequentially arranged along a preset conveying direction, relatively independent material breaking devices 100 are arranged on each material breaking station in a one-to-one correspondence manner, and a material caking processing operation performed on a current material breaking station by the corresponding material breaking device 100 causes caking of a material in the sagger 200 conveyed from a previous station to be further broken and crushed. In fig. 1, the number of the material block breaking stations and the material block breaking devices 100 is five, and in actual production, the number of the material block breaking stations and the material block breaking devices 100 can be set to any number, for example, three, four or more, according to the automatic production requirement and the material caking condition, so that the production requirement can be met. In addition, the conveying direction of the sagger 200 can be designed according to the production requirement. Through repeated and different degrees of fragment processing operations, the materials in the sagger 200 can be fully reduced into powder, so that the automatic production efficiency is improved.

As shown in fig. 1, the multi-station sagger material breaking system 1000 includes: a rack body 300 and a plurality of material breaking apparatuses 100. The plurality of material block breaking devices 100 are fixed and sealed by the rack body 300, and the area where each material block breaking device 100 is located is a material block breaking station.

In the present embodiment, the plurality of material-breaking apparatuses 100 have substantially the same structure and function, and only the different station areas on the multi-station sagger material-breaking system 1000 and the different contact areas with the material in the sagger 200 are different to achieve different breaking effects, and only one of the material-breaking apparatuses 100 will be described in detail herein.

As shown in fig. 2, the material-breaking apparatus 100 includes: the device comprises a shell 40, a material breaking device 10, a sagger conveying device 20 and a sagger lifting device 30.

The housing 40 serves as a support frame for the single material-breaking device 100, on the one hand for the fixed mounting of the material-breaking device 10, the sagger conveyor 20 and the sagger lifting device 30, and on the other hand is provided with all the mechanisms or components required for a single, independent device.

As shown in fig. 3, the casing 40 is a rectangular parallelepiped structure, and the main frame is composed of four support legs 41 and twelve connecting rods 42, wherein the four connecting rods 42 are sequentially and fixedly connected to the top positions of two adjacent support legs 41, the four connecting rods 42 are sequentially and fixedly connected to the middle positions of two adjacent support legs 41, and the last four connecting rods 42 are sequentially and fixedly connected to the lower positions of two adjacent support legs 41, so that the main frame has high strength, and the overall safety of the device is ensured. Furthermore, the wall plates are arranged on all sides of the main body frame, namely, ten wall plates are arranged in total, so that the shell 40 is a sealing structure, and the dust is prevented from overflowing to pollute the working environment of automatic production.

In order to facilitate conveying of the saggar 200 into the shell 40 to perform the block breaking treatment at the current material block breaking station and convey the saggar 200 after the block breaking treatment, a first opening and a second opening are formed in two opposite wall plates of the shell 40, and the saggar conveying device 20 is correspondingly arranged between the first opening and the second opening, that is, the conveying path of the saggar conveying device 20 extends from the first opening to the second opening. Moreover, the size of the first opening and the second opening is set to be at least slightly larger than the size of the sagger 200, so that the sagger 200 can be smoothly conveyed into and out of the housing 40. Optimally, the wall plate of the side of the shell 40 where the first opening and the second opening are to be arranged can be integrally removed, the access space of the sagger 200 is enlarged, and the first opening and the second opening are butted with other equipment before and after the production line or another material block breaking equipment 100 to ensure the tightness of the shell 40 of the current material block breaking station.

Based on the structure of the shell 40 of a single material block breaking device 100, as shown in fig. 1, the rack body 300 is formed by splicing the shells 40 of five material block breaking devices 100, specifically, the first opening and the second opening of two adjacent shells 40 are spliced and fixed, and a structure that the five shells 40 are fixed is formed in sequence. Moreover, in order to realize the flexible application of the single material block breaking device 100, the single material block breaking device 100 is set to be of a symmetrical structure, so that in the installation process of the automatic production line, only the first opening and the second opening of the material block breaking device 100 are required to be respectively and hermetically spliced with the front device and the rear device, and then the conveying direction of the saggars between the first opening and the second opening is set according to the conveying requirement of the whole automatic production line, that is, the conveying direction of the saggar conveying device 20 can be conveyed to the second opening from the first opening, and can also be conveyed to the first opening from the second opening.

Because the single housing 40 is a sealed structure, in order to facilitate the observation of the working process of each device inside, a transparent window can be optionally arranged on the side wall between the first opening and the second opening of the housing 40 or the side wall between the middle connecting rod 42 and the lower connecting rod 42 for observing the internal working process of the material crushing device 100.

In order to facilitate maintenance or sampling of abnormal conditions of each device inside, an openable and closable cabinet door is further provided on the side wall of the housing 40, and the cabinet door is opened to perform a desired operation on the inside. In this embodiment, all wallboards of casing 40 can all set up to the cabinet door structure of card switching, conveniently carry out corresponding operation to each position, based on this, can all be provided with threshold switch on every cabinet door, in case the cabinet door is opened then report to the police immediately, prevent unexpected accident or danger.

Dust is generated in the process of executing the block breaking treatment on the current material block breaking station by the material block breaking device 10, and the dust needs to be removed in time. If by artifical dust removal processing, can only go on when equipment stop operation, the position of removing dust is inside equipment moreover, leads to the dust removal degree of difficulty great, moreover, if the dust solidifies on equipment, also can bring very big potential safety hazard to the safe operation of equipment. Therefore, the best mode is to synchronously carry out automatic dust removal treatment in the process of the broken block treatment. On the basis, a dust removal device 50 is arranged on each material block breaking station, wherein the dust removal device 50 is specifically arranged on the top of the shell 40 and is used for synchronously performing dust removal treatment in the block breaking treatment process of the material block breaking device 10.

As shown in fig. 2 and 4, the dust removing device 50 includes a dust collection cover 51 provided corresponding to the sagger 200, a dust exhaust duct 52 extending from a top wall of the housing 40, and a dust removal driving mechanism 53 connected between the dust collection cover 51 and the dust exhaust duct 52.

The dust collection cover 51 is rotatably connected to the dust removal driving mechanism 53, so that the angle of the dust collection cover 51 can be adjusted. In order to ensure the maximum dust extraction treatment, the dust collection cover 51 is set to be trumpet-shaped and is set opposite to the opening of the sagger 200. In this way, when the dust removal driving mechanism 53 is activated, the generated dust can be maximally sucked into the dust collection cover 51 and discharged to the outside of the housing 40 through the dust discharge duct 52. The dust collection cover 51 has an on-off valve 54 therein for adjusting the opening size of the dust inlet of the dust collection cover 51. The specific on-off valve 54 may be a manual valve or an automatic control valve.

As shown in fig. 1 and 4, in order to achieve the simplicity of installation among the plurality of material block breaking devices 100 and reduce the cost, the dust hoods 51 corresponding to the plurality of material block breaking devices 100 are communicated to the same dust exhaust pipeline 52 for dust removal, and accordingly, the dust removal driving mechanism 53 is located in the region where the plurality of dust hoods 51 meet, and dust removal processing is performed through one dust removal driving mechanism 53. Accordingly, since the distances between the plurality of dust collection covers 51 and the dust removal driving mechanism 53 are different, it is necessary to control the size of the on-off valve 54 in each dust collection cover 51 differently, thereby ensuring the uniformity of the dust removal strength between the dust collection covers 51.

As also shown in fig. 2, the material-breaking device 10 is provided on the top wall of the casing 40, the sagger-conveying device 20 is provided at a position between the first opening and the second opening, and the sagger-elevating device 30 is provided in the lower region of the casing 40 and below the sagger-conveying device 20.

Specifically, with reference to the hollow area 20a formed on the sagger conveyor 20, the material breaking device 10 is located directly above the hollow area 20a and the sagger lifting device 30 is located directly below the hollow area 20a, and the material breaking device 10 corresponds to the hollow area 20 a; when the sagger 200 is conveyed to the position of the hollow area 20a by the sagger conveying device 20, the sagger 200 is lifted upwards to a predetermined height position by the sagger lifting device 30, so that the sagger 200 is separated from the sagger conveying device 20 and is close to the material block breaking device 10, then the sagger is subjected to block breaking processing operation by the material block breaking device 10, and in the block breaking processing operation process, the sagger 200 is supported and protected by the sagger lifting device 30, and the safety of the block breaking processing operation is ensured.

Further, after the material-breaking device 10 completes the breaking process operation, the sagger 200 is driven by the sagger lifting device 30 to descend until the sagger 200 falls on the sagger conveying device 20 again, and then the sagger conveying device 20 performs a further conveying operation.

Based on the above operation processes of conveying, lifting, breaking, descending and re-conveying, the specific structures of the material breaking device 10, the sagger conveying device 20 and the sagger lifting device 30 are as follows:

as shown in fig. 2, the sagger delivering device 20 is disposed at a middle position of the housing 40 and communicates with the first opening and the second opening for delivering the sagger 200 along a delivering path corresponding to a preset delivering direction, and a hollow area 20a corresponding to the material crushing device 10 is formed on the delivering path. Moreover, the hollow area 20a in the saggar conveying device 20 is arranged at the central position, so that the material block breaking equipment 100 is in a symmetrical structure, and the flexibility of installation and use is improved.

As shown in fig. 2 and 5 to 7, the sagger transporting device 20 includes: conveying part 21, mounting part 22, material stopping part 23 and guide part 24.

As shown in fig. 5, the conveying section 21 includes: two first conveyance units 211 and two second conveyance units 212.

The two first conveying units 211 are disposed along the preset conveying direction of the saggar 200 at a predetermined interval, and the two second conveying units 212 are interposed between the two first units and disposed opposite to each other, and the conveying directions of the two first conveying units 211 and the two second conveying units 212 are kept in agreement, thereby conveying the saggar 200 along the preset conveying direction. And, a hollow area 20a corresponding to the material crushing device 10 is formed between the two first conveying units 211 and the two second conveying units 212.

As shown in fig. 5 and 6, the mounting portion 22 serves as a bearing portion of the saggar conveyor 20 for mounting and fixing the two first conveying units 211 and the two second conveying units 212, the dam portion 23 and the guide portion 24, and then the mounting portion 22 is integrally fixed to the housing 40. Specifically, the mounting portion 22 includes two first longitudinal plates 221 disposed at intervals at a predetermined interval, a transverse plate 222 fixedly coupled between the two first longitudinal plates 221, and second longitudinal plates 223 fixedly disposed adjacent to the first longitudinal plates 221, respectively. Next, a flat plate 22 is fixed between the two fixed side plates 21. In addition, the mounting portion 22 further includes two second longitudinal plates 223 fixed at positions respectively adjacent to the first longitudinal plates 221.

The first conveying unit 211 includes a plurality of first conveying rollers 213, and the plurality of first conveying rollers 213 are sequentially disposed on the left and right sides of the broken block processing station along the conveying direction.

The second conveying unit 212 includes a plurality of second conveying rollers 214, and the plurality of second conveying rollers 214 are disposed at upper and lower sides corresponding to the fragment processing stations.

In the present embodiment, the two first conveying units 211 and the two second conveying units 212 are identical in structure and function, and only the arrangement positions are different, and therefore, only one of the first conveying rollers 213 and the second conveying rollers 214 will be described in detail here.

The length of the second conveyor roller 214 is smaller than that of the first conveyor roller 213, that is, the second conveyor roller 214 adopts a roller-breaking design relative to the first conveyor roller 213, so that a hollow area 20a of a sufficient size can be formed between the first conveyor roller 213 and the second conveyor roller 214, and the size of the hollow area 20a is matched with the size of the bottom of the sagger 200. Specifically, the dimension of the bottom of the sagger 200 in the conveying direction is taken as the length, and the dimension in the direction perpendicular to the conveying direction is taken as the width, and based on this, at least the width value is larger than the corresponding width of the hollow region 20a in the dimension of the bottom of the sagger 200, so that when the sagger 200 is at the position of the hollow region 20a, the bottom surface of the sagger 200 can be ensured to be in contact with at least the second conveying roller 214, and the sagger 200 can be supported.

The first conveying roller 213 includes: a first roller shaft 213a, two first ceramic wheels 213b, and two first elastic members 213 c.

The length of the first roller shaft 213a is matched with the interval between the two first longitudinal plates 221 of the mounting part 22, thereby ensuring that both ends of the first roller shaft 213a are rotatably fixed to the two first longitudinal plates 221. The two first ceramic wheels 213b are sleeved on the first roller shaft 213a at a predetermined distance, the two first elastic members 213c are respectively clamped between the two first ceramic wheels 213b and the end portions of the corresponding first roller shaft 213a, and in a normal conveying state, the two first elastic members 213c are in a compressed state, so as to push the corresponding first ceramic wheels 213b to drive the first ceramic wheels 213b to synchronously rotate along with the first roller shaft 213 a.

The second conveying roller 214 includes: a second roller 214a, a second ceramic wheel 214b, and a second elastic member 214 c.

The second roller shaft 214a is rotatably fixed on the first longitudinal plate 221 of the mounting portion 22 through a bearing seat, the second ceramic wheel 214b is sleeved on the second roller shaft 214a and is flush with the corresponding first ceramic wheel 213b on the first roller shaft 213a, the second elastic member 214c is clamped between the second ceramic wheel 214b and the end portion of the second roller shaft 214a, and in a normal conveying state, the second elastic member 214c is also in a compression state, so that the corresponding second ceramic wheel 214b is pushed to drive the second ceramic wheel 214b to rotate synchronously with the second roller shaft 214 a.

All of the first conveying roller 213 and the second conveying roller 214 are driven to rotate by a driving mechanism not shown in the figure, thereby conveying the sagger 200 thereon.

As shown in fig. 2 and 6, the material blocking portion 23 is disposed at a position close to the fragment processing station, and is used for blocking the conveyed sagger 200 to stop conveying and positioning the sagger on the hollow area 20 a. Specifically, the material blocking portion 23 includes a material blocking cylinder 231 and a blocking plate 232.

The material blocking cylinder 231 is fixed on the transverse plate 222 of the mounting part 22, and the position of the transverse plate 222 does not interfere with the lifting movement of the sagger lifting device 30, and is used for providing power to drive the baffle 232 to move telescopically.

The baffle 232 is fixed at the piston rod of the material blocking cylinder 231 and the extending ends of the two guide rods, and in the initial state, the material blocking cylinder 231 is positioned below the first conveying roller 213, and the top of the baffle 232 is not higher than the horizontal plane of the first conveying roller 213, so that the conveying of the sagger 200 is prevented from being interfered. When the sagger 200 is conveyed to a position close to the material block processing station, the baffle 232 is lifted by the power provided by the material blocking cylinder 231 and then contacts the side wall of the sagger 200 to block the sagger 200, so that the sagger 200 stops conveying and stays on the hollow area 20 a.

When the material blocking portion 23 blocks the sagger 200, the friction force between the sagger 200 and the second ceramic wheel 214b is increased, so that the second ceramic wheel 214b overcomes the pushing force applied by the corresponding second elastic member 214c, and the second roller 214a idles in the second ceramic wheel 214b, thereby preventing the sagger 200 from being damaged or worn due to the friction generated between the synchronous rotation of the second ceramic wheel 214b and the bottom of the sagger 200. Similarly, if the bottom of the sagger 200 is in contact with the first ceramic wheel 213b, the friction between the sagger 200 and the first ceramic wheel 213b is increased, so that the first ceramic wheel 213b overcomes the pushing force of the first elastic member 213c to rotate the first roller shaft 213a in the first ceramic wheel 213b, thereby preventing the first ceramic wheel 213b from rubbing the sagger 200 to damage or wear the sagger 200.

The two guide portions 24 have the same structure and function, are disposed at different positions, and are respectively disposed on the upper and lower sides of the conveying direction along the conveying direction, so as to position and guide the sagger 200 during the conveying process of the sagger 200.

As shown in fig. 2, 6 and 7, the guide portion 24 includes: a cylinder 241 and a guide 242. Fig. 7 is a schematic structural view of the guide portion 24 located above in fig. 5.

The cylinder 241 is disposed at a corresponding position of one side of the sagger 200, and is fixed to the second longitudinal plate 223 of the mounting part 22, for providing power to the guide 242 to position the guide 242 at a predetermined distance of one side of the sagger 200.

The guide 242 is for guiding the sagger 200 during transportation, and the guide 242 includes: a cross bar 242a fixedly connected with a piston rod 241a and two guide rods 241b of the cylinder 241, two guide posts 242b fixed at both ends of the cross bar 242a, and two elastic sleeves 242c respectively arranged at the ends of the guide posts 242b facing the sagger 200.

Based on the structure of the guide portion 24, the cylinder 241 drives the piston rod 241a to move in a telescopic manner to drive the transverse plate 421 and the two guide posts 242b to move synchronously, so that the elastic sleeve 242c at the end of the guide post 242b keeps a predetermined distance from the sagger 200. As shown in fig. 2, 6 and 7, in the present embodiment, the two guiding portions 24 are designed to be opposite to each other by the guide rod cylinder 241, so that when the sagger 200 is inclined and deviated during transportation, the sagger 200 is guided and positioned by the pushing action of the four elastic sleeves 242c on both sides on the sagger 200, so that the sagger 200 is kept stable during transportation. Here, the elastic member 423 is made of an elastic material, such as a polyurethane material, so as to ensure that the elastic member 423 is in soft contact when providing a resisting force to the sagger 200 during the guiding and positioning processes, thereby preventing the sagger 200 from being damaged or worn by rigid contact.

As also shown in fig. 2, the sagger elevating device 30 is fixed to the casing 40 and located right below the hollow area 20a of the sagger transporting device 20, and lifts the sagger 200 transported to the hollow area 20a up to a predetermined height position to detach the sagger 200 from the sagger transporting device 20, facilitating the material lumping processing operation.

As shown in fig. 2, 8 and 9, the sagger raising and lowering means 30 includes: an attachment portion 31, a driving portion 32, a support portion 33, and a support portion 34.

As shown in fig. 2, the mounting portion 31 is provided at a predetermined height position below the chipping processing station, and serves as a main body mounting portion of the sagger raising and lowering device 30 for mounting and fixing the driving portion 32, the receiving portion 33, and the supporting portion 34.

As also shown in fig. 8 and 9, the mounting portion 31 includes: a plurality of positioning posts 311 and a mounting base 312.

In the present embodiment, the number of the positioning columns 311 is four, and the four positioning columns 311 are sequentially fixed on two sides of the hollow area 20a, specifically on the frame of the material crushing apparatus 100, along the conveying direction of the sagger conveying device 20. The mounting seat 312 is a flat plate structure, and is fixed on a predetermined position on the positioning column 311 away from the sagger conveying device 20 after being penetrated by the plurality of positioning columns 311, and the plane direction of the mounting seat 312 is consistent with the conveying direction of the sagger conveying device 20.

The driving portion 32 is fixed on the mounting portion 31 and disposed toward the chipping processing station, and specifically, the driving portion 32 is fixed on the top surface of the mounting base 312 toward the chipping processing station for driving the sagger 200 to be lifted to a predetermined height position and also for driving the sagger 200 to be lowered and dropped on the sagger conveyor 20.

Specifically, the driving part 32 includes a first cylinder 321 and a plurality of guide mechanisms 322.

The first cylinder 321 is fixed on the mounting seat 312 for providing power to drive the supporter 33 to ascend and descend.

In this embodiment, the number of the guiding mechanisms 322 is four, and the guiding mechanisms 322 are respectively disposed on two opposite sides of the first cylinder 321, that is, are uniformly disposed on the periphery of the first cylinder 321, and the plurality of guiding mechanisms 322 have the same structure and function except for different positions.

One end of the guiding mechanism 322 is movably connected to the mounting seat 312, and the other end is fixedly connected to the supporting portion 33 for guiding the ascending and descending process of the supporting portion 33.

The supporting portion 33 is connected to the driving portion 32 and located above the driving portion 32, and is used for supporting the sagger 200 and lifting the sagger 200 to a predetermined height position under the driving of the driving portion 32.

Specifically, the receiver 33 includes: a bottom plate 331, two brackets 332, a support plate 333, and an elastic pad 334.

The base plate 331 is fixedly connected to the driving unit 32, i.e., to the extending end of the piston rod of the first cylinder 321, and the base plate 331 is driven to ascend and descend by the telescopic movement of the piston rod.

The two brackets 332 are fixed on the bottom plate 331 at a predetermined interval, the two brackets 332 have the same structure and function, and the brackets 332 are C-shaped plates having a predetermined thickness and a sharp angle and are fixed on the bottom plate 331 in an arch bridge manner.

The pallet 333 is fixed on the top surfaces of the two supports 332, and the pallet 333 corresponds to the hollow area 20a of the magazine conveyance device 20. In addition, the size of the supporting plate 333 is slightly smaller than the size of the hollow area 20a, so that the supporting plate 333 can penetrate through the hollow area 20a, that is, the supporting plate 333 can move back and forth in the hollow area 20a without being obstructed under the driving of the first cylinder 1, thereby driving the sagger 200 to synchronously move up and down; while ensuring sufficient contact area between pallet 333 and sagger 200.

The elastic pad 334 is made of soft material such as rubber pad, and the elastic pad 334 is the same as the support plate 333 in size and fixed on the top surface of the support plate 333, so that the elastic pad 334 is in direct contact with the sagger 200, which is convenient for reducing the thrust force of the material block breaking device 10 on the sagger 200 and the whole sagger lifting device 30 in the material block breaking process, and protecting the sagger 200 safely.

The supporting portion 34 is disposed on the mounting portion 31 and located below the supporting portion 33, and is configured to support the supporting portion 33 in the material block breaking process, so as to avoid damage to the driving portion 32 due to the pushing force applied by the material block breaking device 10, specifically, prevent damage to the first air cylinder 321.

Specifically, the support portion 34 includes two support members 341 symmetrically disposed on opposite sides of the driving portion. Here, the two support members 341 have the same structure and function, and are used for supporting the receiver 33 from both sides of the receiver 33 during the material block breaking process performed by the material block breaking device 10, thereby supporting the sagger 200.

As shown in fig. 8, the supporting member 341 includes: a pillar 341a, and a second cylinder 341 b.

One end of the pillar 341a is rotatably connected to the mounting seat 312 at a position corresponding to the edge of the bottom plate 331, so that the rotation range of the pillar 341a extends from a vertical state to an outward inclination. And the other end of the pillar 341a has a plane structure to facilitate sufficient contact with the base plate 331 so as to support the base plate 331.

One end of the second cylinder 341b is rotatably connected to the mounting seat 312, and the piston rod at the other end is rotatably connected to the middle region of the corresponding upright 341a, so that the corresponding upright 341a can be driven by the telescopic movement of the piston rod of the second cylinder 341b to switch the state between the vertical state and the inclined state. When the upright 341a is switched from the vertical state to the inclined state, the upright 341a is no longer in contact with the bottom plate 331, so as to reserve a descending space, which will not hinder the descending of the bottom plate 331, and facilitate the whole descending of the sagger 200 driven by the bottom plate 331. Here, in order to facilitate the lowering of the bottom plate 331, the second cylinder 341b is disposed to be inclined from the end of the mounting seat 312 toward the middle thereof, that is, the two columns 341a are formed in a bell mouth shape when the first cylinder 321 moves the bottom plate 331 down. Also, in the initial state, the two pillars 341a of the two supporting members 341 form a bell mouth shape, that is, each pillar 341a is in an outward inclined state.

As shown in fig. 2, the material-breaking device 10 is disposed on the top wall of the housing 40 and is located right above the hollow area 20a of the sagger-conveying device 20, and is used for breaking the sagger 200 lifted and supported by the sagger-lifting device 30.

As shown in fig. 2 and fig. 10 to 12, the material breaking device 10 includes: a breaking part 11, a driving part 12, a detecting part 13 and a flexible connecting part 14.

The breaking portion 11 is driven to extend into the sagger 200 and press the material to perform breaking processing.

The driving part 12 is connected with the block breaking part 11 and located above the block breaking part 11, and is used for driving the block breaking part 11 to move towards the sagger 200 in a telescopic manner, so that the block breaking part 11 is pressed against or away from the material.

The flexible connecting portion 14 is connected between the block breaking portion 11 and the driving portion 12, and is used for realizing flexible connection between the block breaking portion 11 and the driving portion 12 when the block breaking portion 11 is pressed against the material in the sagger 200, so that on one hand, block breaking processing is facilitated, and on the other hand, damage to the structure of the block breaking portion 11 and the structure of the driving portion 12 caused by inclination of the block breaking portion 11 due to pressing against the block-shaped material is protected.

As shown in fig. 2 and 10, the breaking block portion 11 includes: a first mounting plate 111 and a blade assembly 112.

The first mounting plate 111 is a planar plate having a thickness, length and width, and is primarily used to secure the blade assembly 112. Specifically, the blade assembly 112 is fixed on the side of the first mounting plate 111 facing the sagger 200, and the driving part 12 drives the first mounting plate 111 to move toward the sagger 200 through the side of the first mounting plate 111 opposite to the sagger 200 so as to drive the blade assembly 112 to extend into the sagger 200 for the material block breaking process.

In this embodiment, in order to facilitate the blade assembly 112 to perform better block breaking processing on the block-shaped materials in the sagger 200, the blade assembly 112 may be configured to have a preset shape according to actual requirements, specifically, any shape such as a cross-shaped blade, a grid-shaped blade, or a grid-shaped blade, and the shape of the blade assembly 112 is configured according to the caking size and number of the materials, so as to achieve more sufficient contact with the materials, thereby improving the block breaking efficiency. In the configuration shown in fig. 2 and 10-12, the blade assembly 112 is a cross-type blade that enables the breaking of larger blocks.

Based on this, in the multi-station sagger material breaking system 1000 shown in fig. 1, in order to improve the overall breaking efficiency of the multi-station sagger material breaking system 1000, the sizes of the contact areas of the corresponding blade assemblies 112 in the plurality of material breaking devices 100 are set to be different, so as to achieve different breaking degrees and effects, and the materials with different agglomeration sizes can be fully crushed into powder through multiple times of breaking treatments with different degrees; the blade assemblies 112 of the plurality of material-breaking devices 100 are preferably sized to have increasing contact areas in the conveying direction.

As shown in fig. 2, 10 and 11, the driving section 12 includes: a hydraulic cylinder 121, a second mounting plate 122, and a plurality of guide mechanisms 123.

The hydraulic cylinder 121 serves as a power source for the breaking unit 11, and the hydraulic cylinder 121 has a piston rod 121a, and the driving unit 11 is driven to move up and down with respect to the sagger 200 by the telescopic movement of the piston rod.

The second mounting plate 122 is similar to the first mounting plate 111 in structure and shape, and the second mounting plate 122 is located right above the first mounting plate 111 and is used for fixing the hydraulic cylinder 121, specifically, the hydraulic cylinder 121 is fixed on a top surface of the second mounting plate 122 opposite to the first mounting plate 111, and the piston rod 121a movably penetrates through the second mounting plate 122 and then is connected with the first mounting plate 111, so as to drive the first mounting plate 111 and the blade assembly 112 fixed thereon to synchronously move up and down. Here, the piston rod 121a is not rigidly and fixedly connected to the first mounting plate 111, but is flexibly connected through the flexible connecting portion 14, specifically, when the blade assembly 112 presses against a block in the material, adaptive position and inclination adjustment between the piston rod 121a and the first mounting plate 111 is achieved, so as to avoid damage to the blade assembly 112, the first mounting plate 111, and the piston rod 121 a.

The plurality of guide mechanisms 123 are fixed to the second mounting plate 122, are provided apart from the hydraulic cylinder 121, and guide the lifting movement of the entire block breaking unit 11. In the present embodiment, as shown in fig. 2 and 11, the number of the guide mechanisms 123 is four, and the guide mechanisms 123 are respectively provided at symmetrical positions centering on the hydraulic cylinder 121, and all the guide mechanisms 123 are identical in structure and function, and are provided at different positions only on the second mounting plate 122.

As shown in fig. 10 and 11, the guide mechanism 123 includes: a guide sleeve 123a and a guide post 123 b.

The guide sleeve 123a is a hollow sleeve having a sliding groove and disposed at a certain length, and is fixed at a corresponding position of the second mounting plate 122. The guide post 123b penetrates through the guide sleeve 123a and is connected with the guide sleeve in a sliding fit manner, namely, under the driving of the power action when the piston rod 121a extends and retracts, the guide post 123b can move axially relative to the guide sleeve 123 a; and, the guide post 123b extends from the guide sleeve 123a and is fixedly connected to the first mounting plate 111 at an end thereof adjacent to the first mounting plate 111, so as to guide the movement of the blade assembly 112 when the guide post 123b moves back and forth along the axial direction of the guide sleeve 123 a.

During the process of the blade assembly 112 for breaking the lump material, the lump material is crushed to be reduced into powder, so that dust is inevitably generated in the process, and when the dust enters between the guide sleeve 123a and the guide post 123b, the guide post 123b is easily locked and cannot move; therefore, in order to facilitate the discharge of the dust generated during the lump breaking process and ensure that the guide post 123b can move smoothly in the axial direction along the guide sleeve 123a, a groove of a predetermined size is provided on the inner wall of the guide sleeve 123a facing the guide post 123b, and the groove is configured to extend from the upper end to the lower end of the guide sleeve 123a in the axial direction thereof, forming an open discharge space, so that the dust is discharged from the groove, and the guide post 123b is prevented from being locked.

In addition, the blade assembly 112 extends into the sagger 200 to crush and break the materials, and the size of the sagger 200 is limited, so that the blade assembly 112 cannot be completely controlled to move according to the telescopic moving stroke of the piston rod 121 a; therefore, the detection unit 13 is attached to the guide post 123b of any of the guide mechanisms 123, thereby controlling the moving stroke of the piston rod 121 a.

Specifically, as shown in fig. 2 and 10, the detection section 13 includes an upper position sensor 131 and a lower position sensor 132.

When the piston rod 121a is in the retracted in-place state, the retracted in-place state may be the retracted in-place state of the piston rod 121a itself, or the piston rod 121a may be retracted to separate the blade assembly 112 from the saggar 200, an upper in-place detection block is disposed at a predetermined position in the axial direction of the guide post 123b, and the upper in-place sensor 131 is disposed at a position corresponding to the upper in-place detection block and is configured to determine that the piston rod 121a is in the retracted in-place state according to the sensed position of the upper in-place detection block when the piston rod 121a is retracted in place, thereby stopping retraction.

When the piston rod 121a is in the extended in-place state, the extension length in the extended in-place state is matched according to the depth of the sagger 200, a lower in-place detection block is arranged at a predetermined position in the axial direction of the guide post 123b, and the lower in-place sensor 132 is arranged at a position corresponding to the lower in-place detection block and used for judging that the piston rod 121a is in the extended in-place state according to the position of the sensed lower in-place detection block when the piston rod 121a is extended in place, so as to stop the extension.

In the embodiment, the upper in-place detecting block and the lower in-place detecting block are both disposed in the axial region of the guide post 123b above the guide sleeve 123a, and the upper in-place sensor 131 and the corresponding upper in-place detecting block are located right above the lower in-place sensor 132 and the corresponding lower in-place detecting block, so as to control the telescopic stroke (i.e., the telescopic in-place state) of the telescopic rod 121a in general.

As shown in fig. 10 and 11, the flexible connecting portion 14 includes: universal movable joint 141, elastic buffer cover 142 and dustproof protective sheath 143.

One end of the universal movable joint 141 is fixedly connected with the piston rod 121a, the other end is fixedly connected with the center position of the first mounting plate 111, when the blade assembly 112 abuts against a block in the material, the rotating amount in the corresponding direction generated by the universal movable joint 141 adapts to the position offset and the inclination of the blade assembly 112 and the first mounting plate 111 caused by the block, and secondly, under the cooperation of the fixing action of the plurality of guide mechanisms 123, the blade assembly 112 can crush the block of the material.

In the above-mentioned detection portion 13, the upper in-place sensor 131 and the upper in-place detection block and the lower in-place sensor 132 and the lower in-place detection block may adopt paired photoelectric switches to realize sensing detection, that is, the expansion and contraction control of the piston rod 121a is realized by means of the photoelectric switches. In order to avoid the failure of the telescopic control of the piston rod 121a caused by the failure of the photoelectric switch, a mechanical limit buffer structure is additionally arranged to ensure the accurate limit of the telescopic control. In particular to a method for preparing a high-performance nano-silver alloy,

the guide mechanism 123 further includes a limiting buffer 123c disposed at a predetermined position in the axial direction of the guide post 123b, the limiting buffer 123c is an elastic sleeve made of polyurethane material and disposed on the guide post 123b and located above the guide sleeve 123a, and when the guide post 123b moves downward along the guide sleeve 123a, the limiting buffer 123c abuts against the top of the guide sleeve 123a to limit the extending length of the piston rod 121a, that is, to limit the depth of the blade assembly 112 extending into the sagger 200, so as to avoid damaging the sagger 200. The elastic buffer sleeve 142 is sleeved outside the universal movable joint 141 and is a flexible structure made of polyurethane material, and one end of the elastic buffer sleeve 142 facing the first mounting plate 111 is fixedly connected with the first mounting plate 111; therefore, when the piston rod 121a retracts, the first mounting plate 111 and the blade assembly 112 are driven to ascend synchronously, and when the piston rod 121a retracts to the right position, the other end of the elastic buffer sleeve 142 is enabled to be abutted against the second mounting plate 122, so that the universal movable joint 141 is protected on one hand, and the piston rod 121a is buffered and limited in the retracting movement on the other hand.

When the limiting buffer member 123c moves downwards to the top of the abutting guide sleeve 123a, the lower in-place sensor 132 can sense the corresponding lower in-place detection block. Moreover, when the elastic buffer sleeve 142 moves upwards to abut against the second mounting plate 122, the upper in-place sensor 131 can sense the corresponding upper in-place detection block, so that dual guarantee of photoelectric control limitation and mechanical limitation is realized.

Further, in order to avoid the dust that produces among the broken piece process to lead to universal movable joint 141 to produce the locking condition, further overlap in the outside of elastic buffer sleeve 142 and be equipped with dustproof protective sheath 143, be used for carrying out better dustproof protection to universal movable joint 141.

In order to realize more accurate control of the extending-in-place position and the retracting-in-place position of the piston rod 121a and prevent the occurrence of poor limiting precision and even failure of the limiting buffer 123c and the elastic buffer sleeve 142, a detection part 13 is arranged on any one of the plurality of guide mechanisms 123, and the extending-in-place position and the retracting-in-place position of the piston rod 121a are detected and judged through the detection part 13.

Based on the above structure, for the single material-breaking device 100, the operation processes of the sagger-conveying device 20, the sagger-lifting device 30 and the material-breaking device 10 are as follows:

the conveying process comprises the following steps: the first roller shaft 213a and the second roller shaft 214a are driven to rotate, the first ceramic wheel 213b and the second ceramic wheel 214b synchronously rotate due to the abutting action of the first elastic member 213c and the second elastic member 214c, the sagger 200 is conveyed onto the first ceramic wheel 213b from one end, and the conveying of the sagger 200 is gradually realized. The material stopping cylinder 231 is driven to drive the baffle 232 to extend to a height position higher than the first conveying roller 213, the sagger 200 is stopped and stops conveying, at this time, the friction force between the sagger 200 and the second ceramic wheel 214b is increased, so that the second ceramic wheel 214b overcomes the pushing force of the corresponding second elastic element 214c and does not rotate any more, and the second roller shaft 214a is kept idle in the second ceramic wheel 214 b.

And (3) lifting process: the first cylinder 321 drives the piston rod to extend to drive the supporting portion 33 to integrally and synchronously extend, after the elastic pad 334 contacts with the sagger 200, the supporting portion 33 completely supports the sagger 200 to separate from the sagger conveying device 20 along with the further extension of the piston rod, the piston rod is stopped to extend until the sagger 200 is lifted to a preset height position, and the guide mechanism 322 guides in the extending process of the supporting portion 33. After the supporting portion 33 is driven by the driving portion 32 to lift to the proper position, the second cylinder 341b in the supporting assembly 341 drives the piston rod to extend, the upright 341a is connected to the end of the mounting seat 312, the second cylinder 341b is connected to the end of the mounting seat 312, and the second cylinder 341b is connected to the other end of the upright 341a, so that the upright 341a is switched from the inclined state to the vertical state.

And (3) a block breaking process: the oil cylinder supplies oil to extend the piston rod 121a, so as to drive the first mounting plate 111 and the blade assembly 112 to extend into the sagger 200, and in the extending process of the piston rod 121a, the guide posts 123b of all the guide mechanisms 123 are simultaneously driven to move along the guide sleeves 123a, so that the extending direction of the blade assembly 112 is guided; the blade assembly 112 gradually contacts the material and presses against the blocky material during the process of extending, so as to break the blocky material; with the continuous extension of the piston rod 121a, when the limiting buffer member 123c moves downward to abut against the top of the guide sleeve 123a or the lower in-place sensor 132 detects a corresponding lower in-place detection block, the piston rod 121a is controlled to stop extending. Similarly, the retraction of the piston rod 121a drives the blade assembly 112 to move upward and gradually disengage from the sagger 200. According to production needs, the materials can be broken fully by lifting repeatedly. During the block breaking process, the material block breaking device 10 applies a downward pushing force to the sagger 200, which is partially absorbed by the elastic action of the elastic pad 334 on one hand, and is supported by the two supporting members 341 providing an upward supporting force to the bottom plate 331 on the other hand.

And (3) a descending process: the second cylinder 341b drives the piston rod to retract, and drives the corresponding column 341a to switch from the vertical state to the inclined state, so as to avoid interference on the descending of the bottom plate 331. Then, the first cylinder 321 drives the piston rod to retract, which drives the supporting portion 33 and the sagger 200 to descend synchronously, and when the elastic element 34 descends to a level lower than the horizontal position of the sagger conveying device 20, the sagger 200 falls on the sagger conveying device 20 again and is separated from the elastic pad 334, and the process is stopped until the piston rod retracts to the right position.

And (3) a re-conveying process: the material blocking cylinder 231 drives the baffle 232 to retract, so that the sagger 200 is continuously and automatically conveyed along the conveying direction.

Through the processes of conveying, lifting, block breaking, descending and re-conveying, the sagger material block breaking treatment process on the current material block breaking station is completed.

Then, carry out foretell broken piece processing procedure respectively on a plurality of material broken piece stations, the saggar realizes automated transportation through saggar conveyor between a plurality of material broken piece stations moreover, through the broken piece processing operation of multiple different degree, different angles, makes the material in the saggar fully restore into powdered, and whole processing procedure is accomplished through the automation moreover, has improved broken piece efficiency and automated production efficiency greatly.

In above-mentioned sagger conveyor's structure, the second conveying roller is compared in first conveying roller for adopting the broken shaft design, has formed the lift space that sagger lifting devices corresponds, makes things convenient for jacking and decline, furthest increases jacking area and to the area of contact that the sagger bore.

In the structure of the sagger lifting device, the jacking structure of the original square-tube bridge structure is changed into the supporting part of the panel structure, the contact area of the sagger lifting device and the sagger is changed from 84 square centimeters to 900 square centimeters, the contact area is increased by ten times, the corresponding pressure of the sagger is only 1/11 of the original design, the contact part is changed from original carbon steel to a rubber pad, and the safety performance of the sagger is protected to the maximum extent.

In the structure of the material block breaking device, the driving part adopts a hydraulic design, and the pressure of the broken block is adjustable between 0 and 10MPA, compared with the original mechanical lifting driving structure, the energy consumption is saved, the pressure range is expanded, the adverse effect of the abrasion of a copper nut in the mechanical lifting structure on the quality of the material is avoided, the service life of the driving part is prolonged, and the broken block is more convenient and efficient. Thirdly, on the basis of a detection part for limiting in a photoelectric switch control mode, mechanical limiting formed by a limiting buffer part and an elastic buffer sleeve is added, so that the sagger can still limit on the premise that all photoelectric switches fail, and the safety of the sagger is ensured; and adopt the buffering design, avoid hard contact, guaranteed the safety and the life of all devices. Further, for the accuracy that improves the electrical control mode, can also change into metal proximity sensor by photoelectric sensor with the spacing electrical apparatus control that goes up and down, the sensor that targets in place promptly all adopts proximity sensor with the sensor that targets in place down, what correspond this moment targets in place the detection piece and targets in place down the detection piece respectively for fixing the metal block on the guide pillar, respond to through adopting proximity sensor, the problem of dust to photoelectric sensor's influence has been solved, it can accurate sense the corresponding detection piece and realize that the lift is spacing to ensure proximity sensor, improve the rate of accuracy greatly. Finally, the original flange connection is changed into universal loose joint design, and the rigid connection is changed into universal loose joint connection, so that the hard friction of the mechanism is avoided, and the safety and the service life of the hydraulic cylinder are protected.

Through above sagger lift process, on lifting the sagger to predetermined high position, carry out broken block of material processing operation again after making the sagger break away from with sagger conveyor mutually, like this, be convenient for on the one hand break the piece and handle, on the other hand, can wholly protect sagger conveyor, the thrust that avoids broken block of material device to carry out causes the damage to sagger conveyor, and simultaneously, the surface contact of sagger elevating gear and the bottom of sagger compares in the contact between the ceramic wheel on sagger and sagger conveyor's the conveying roller, realizes the protection to the sagger, guarantees the security and the reliability of broken block processing.

In addition, the material breaking device, the sagger conveying device and the sagger lifting device are designed by adopting independent modules respectively, so that the sagger conveying device is convenient to install, disassemble and maintain and convenient to adjust.

In the present embodiment, the rack body is formed by sequentially splicing the shells of the plurality of material block breaking devices, and in the present invention, the rack body may further be configured as a hollow structure covering the plurality of material block breaking stations and the plurality of material block breaking devices, and the internal space of the rack body is divided into a plurality of regions to form the plurality of material block breaking stations, that is, the material block breaking stations provide a production operation region for the material block breaking devices, so that the plurality of material block breaking devices perform multiple block breaking processing operations, and an input port and an output port are provided on two opposite side walls of the rack body along the conveying direction, so that the sagger enters and exits the plurality of material block breaking stations.

While specific embodiments of the invention have been described above, it will be appreciated by those skilled in the art that this is by way of example only, and that the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the spirit and scope of the invention, and these changes and modifications are within the scope of the invention.

Claims (10)

1. The utility model provides a broken piece system of multistation sagger material for to the sagger of burning completion in the kiln carry and right along predetermineeing direction of delivery the material in the sagger carries out the broken piece processing operation of plural times, a serial communication port, includes:

a frame body;

the material breaking stations are sequentially arranged in the rack body along the conveying direction;

and the material block breaking devices are arranged on the material block breaking stations in a one-to-one correspondence manner and are used for carrying out a plurality of times of block breaking processing operations on the materials along the conveying direction.

2. The multi-station sagger material breaking system of claim 1, wherein:

each material breaking equipment comprises:

a sagger conveying device having a conveying path corresponding to the conveying direction and for conveying the sagger along, the conveying path having a hollow area formed thereon;

a sagger lifting device arranged below the hollow area and used for lifting the sagger conveyed to the hollow area to a preset height position so as to be separated from the sagger conveying device;

and the material block breaking device is arranged above the hollow area and used for carrying out block breaking treatment operation on the saggar supported by the saggar lifting device.

3. The multi-station sagger material breaking system of claim 2, wherein:

the material breaking device comprises a blade assembly which has a preset contact area with the material and is used for breaking and crushing the material.

4. The multi-station sagger material breaking system of claim 3, wherein:

the plurality of material breaking devices are arranged to have different contact areas corresponding to the blade assemblies.

5. The multi-station sagger material breaking system of claim 3, wherein:

the plurality of material breaking devices are arranged so that the sizes of the contact areas of the corresponding blade assemblies gradually increase along the conveying direction.

6. The multi-station sagger material breaking system of claim 2, wherein:

each material block breaking device is also provided with a shell for fixedly sealing the sagger conveying device, the sagger lifting device and the material block breaking device, the side walls of the shell, which are opposite along the conveying direction, are provided with a first opening and a second opening,

the frame body by the casing concatenation forms, adjacent two the casing first opening with the second opening is spliced fixedly mutually.

7. The multi-station sagger material breaking system of claim 5, wherein:

and the plurality of material block breaking stations are respectively and correspondingly provided with a dust removal device, and the dust removal device is provided with a dust collection cover facing the saggar.

8. The multi-station sagger material breaking system of claim 6, wherein:

the dust collecting covers corresponding to the material block breaking stations are communicated to a dust removing driving mechanism.

9. The multi-station sagger material clod breaking system of claim 7, wherein:

each dust collection cover is provided with a switch valve, and the size of the opening of the corresponding switch valve is adjusted according to the distance between the dust collection cover and the dust removal driving mechanism.

10. The multi-station sagger material breaking system of claim 1, wherein:

the rack body is of a hollow structure which covers the plurality of material breaking stations and the plurality of material breaking devices, and an input port and an output port are formed in two opposite side walls of the rack body along the conveying direction.

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