CN115366228B

CN115366228B - Setting device is used in production of shale sintering hollow brick

Info

Publication number: CN115366228B
Application number: CN202211300963.4A
Authority: CN
Inventors: 魏宾
Original assignee: Xuzhou Jingu New Wall Material Co ltd
Current assignee: Xuzhou Jingu New Wall Material Co ltd
Priority date: 2022-10-24
Filing date: 2022-10-24
Publication date: 2023-03-24
Anticipated expiration: 2042-10-24
Also published as: CN115366228A

Abstract

The invention belongs to the technical field of hollow brick processing and shaping equipment, and discloses a shaping device for producing a shale sintered hollow brick, which comprises a first support frame and a base communicated with one side of the lower end of the first support frame, wherein the inner side of the top end of the first support frame is fixedly connected with a connecting block positioned above the base, the top of the connecting block is fixedly connected with a second support frame, the inner part of the lower end of the second support frame is fixedly connected with a shaping assembly, and the front side and the rear side of the shaping assembly are fixedly connected with mounting blocks. According to the shale forming machine, the extrusion assembly, the lifting assembly and other structures are matched, the hydraulic cylinder and the servo motor are started, the hydraulic cylinder can drive the second rectangular plate and the extrusion block to move downwards together when the hydraulic cylinder operates, and the shale placed in the forming bin body can be simultaneously pressed and formed up and down due to the opposite movement of the lifting block and the extrusion block, so that the forming effect on the shale is greatly improved.

Description

Setting device is used in production of shale sintering hollow brick

Technical Field

The invention belongs to the technical field of hollow brick processing and shaping equipment, and particularly relates to a shaping device for producing a shale sintered hollow brick.

Background

The shale hollow brick is a hollow heat-insulating building square material, namely a shale hollow brick, which is prepared by mechanically pressurizing shale serving as a main body, adding coal gangue and cement serving as a bonding substance; can use relevant setting device before using shale sintering hollow brick, and then guarantee the subsequent normal use of hollow brick, nevertheless utilize the setting device to stereotype the hollow brick among the prior art and still have the drawback:

setting device is in the in-service use in-process, need place the shale earlier in the design storehouse, through pressing the shale of placing in the design storehouse from last down afterwards with this realization to the design effect of shale sintered hollow brick, at the during operation, only adopt the one side to press the method of design, lead to the atress inequality easily, and reduced follow-up production availability factor to shale sintered hollow brick by a wide margin, need artifical manual shale of will finalizing the design to take out from the inside in design storehouse after finalizing the design simultaneously, consume more human cost, holistic work efficiency has further been influenced, consequently, need improve it.

Disclosure of Invention

In order to achieve the purpose, the invention provides the following technical scheme: a shaping device for shale sintering hollow brick production comprises a first support frame and a base communicated with one side of the lower end of the first support frame, wherein the inner side of the top end of the first support frame is fixedly connected with a connecting block positioned above the base, the top of the connecting block is fixedly connected with a second support frame, a shaping assembly is fixedly connected inside the lower end of the second support frame, mounting blocks are fixedly connected to the front side and the rear side of the shaping assembly, the bottom ends of the two mounting blocks are fixedly connected with the base, an extrusion assembly is fixedly mounted at the top end of the second support frame, the bottom end of the extrusion assembly penetrates through the second support frame and extends into the second support frame, a lifting assembly is movably sleeved inside the lower end of the shaping assembly, a servo motor is fixedly mounted on the back of the base, one end of an output shaft of the servo motor is fixedly connected with a first bevel gear, the top of the first bevel gear is fixedly connected with a first screw rod, and the top of the first screw rod is in threaded sleeve connection with the lifting assembly;

the surface of the first bevel gear is connected with a second bevel gear in a meshed mode, one side, far away from the servo motor, of the second bevel gear is fixedly connected with a second screw rod, the surface of the second screw rod is in threaded sleeve connection with a pushing assembly, and the top end of the pushing assembly is connected with the connecting block in a sliding and clamping mode;

the pushing assembly comprises two pushing blocks and two sliding blocks, the bottoms of the two sliding blocks are fixedly connected with the pushing blocks, the pushing blocks are slidably connected with the connecting block through the two sliding blocks, the bottom of each pushing block is fixedly connected with a movable plate, the inner wall of the lower end of each movable plate is sleeved with the surface thread of the second screw rod, one side of the bottom of each pushing block, far away from the corresponding movable plate, is slidably connected with a telescopic rod, and the inner wall of the lower end of each telescopic rod is movably sleeved with the surface of the second screw rod;

the area size of the inner cavity of the shaping bin body is in adaptive connection with the area sizes of the surfaces of the extrusion block and the lifting block, the inner cavity of the shaping bin body is communicated with each other, and the inner wall of the shaping bin body, the surfaces of the extrusion block and the lifting block are smooth;

one side wall that the third rectangular plate is close to the base is connected with base swing joint, one side and the outer end swing joint of base upper segment part of third rectangular plate bottom.

Among the above-mentioned technical scheme, it is preferred, the design subassembly includes first rectangular block, the front and the back of first rectangular block all with second support frame fixed connection, the equal fixed mounting in both sides of first rectangular block has spacing draw-in groove, the upper end of first rectangular block both sides all with installation piece fixed connection, five design storehouse bodies have been seted up to the inside equidistance on first rectangular block top.

Among the above-mentioned technical scheme, it is preferred, the extrusion subassembly includes second rectangular plate and pneumatic cylinder, both ends all pass through slider and second support frame swing joint around the second rectangular plate both sides, the bottom equidistance fixed mounting of second rectangular plate has five extrusion pieces, the middle part fixed mounting on second support frame top has the pneumatic cylinder, the bottom of pneumatic cylinder runs through the second support frame and extends to the inside of second support frame and with the top fixed connection of second rectangular plate, the equal fixedly connected with spacing post in both sides at second rectangular plate top, two the upper end of spacing post all runs through the second support frame and extends to the top of second support frame and with the inner wall swing joint of second support frame.

Among the above-mentioned technical scheme, it is preferred, the lifting subassembly includes the third rectangular plate, the bottom and the first screw rod screw thread of third rectangular plate cup joint, the equal fixed mounting in both sides of third rectangular plate has spacing fixture block, two the equal activity joint in the inside of spacing draw-in groove in upper end of spacing fixture block, the equidistant fixed mounting in top of third rectangular plate has five lifting pieces, five the equal swing joint in the inside of design storehouse body in upper end of lifting piece.

In the above technical scheme, preferably, the base is composed of an upper section and a lower section, the upper section of the base is integrally in an inclined plane shape, the width of the bottom end of the upper section of the base is larger than that of the lower section of the base, the lower section of the base is in a rectangular shape, the lower end of the outer side wall of the lower section of the base is fixedly connected with the first support frame, and the inclined plane of the upper section of the base is fixedly provided with the limit baffle.

In the above technical solution, preferably, the height value of the second support frame is greater than the height value of the hydraulic cylinder during lifting.

Compared with the prior art, the invention has the following beneficial effects:

according to the shale shaping device, the extruding and shaping effects on shale are further improved by arranging the matching of structures such as the extruding assembly and the lifting assembly, the hydraulic cylinder and the servo motor are started, the hydraulic cylinder can drive the second rectangular plate and the extruding block to move downwards together by operating the hydraulic cylinder, so that the extruding block gradually moves to the inside of the shaping bin body, meanwhile, the first bevel gear can drive the third rectangular plate and the lifting block to move upwards gradually by operating the servo motor, and at the moment, shale placed in the shaping bin body can be pressed and shaped up and down simultaneously by the opposite movement of the lifting block and the extruding block, so that the shaping effect on the shale is greatly improved;

according to the invention, through the matching of the servo motor and the pushing assembly and other structures, the taking of shaped shale by workers is facilitated, when the servo motor rotates reversely, the first bevel gear drives the third rectangular plate and the lifting block to move downwards together through the first screw rod, and drives the shale shaped at the top of the lifting block to be separated out from the inside of the shaped bin body together, meanwhile, the second bevel gear drives the pushing block to move towards the lifting block through the second screw rod, along with the movement of the pushing block, when the third rectangular plate is not in contact with the top of the base and moves, the pushing block can just push the shale placed at the top of the lifting block, so that the shale slides downwards from the top of the lifting block through the inclined plane at the upper end of the base, the taking of the workers is facilitated, a large amount of labor time is saved, and the working efficiency is greatly improved;

according to the invention, the collection effect of the shaped shale is further improved by matching the structures such as the base and the pushing assembly, the shale can well slide downwards due to the design of the inclined plane at the upper end of the base, and the stability of the shale in sliding is improved due to the design of the inclined plane surface limiting baffle, so that the subsequent production matching use efficiency is greatly improved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the backside structure of the present invention;

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

FIG. 4 is a schematic view of a portion of the enlarged structure at A in FIG. 3;

FIG. 5 is a schematic cross-sectional view of the front face of the present invention;

FIG. 6 is a schematic view showing the structural matching relationship between the first support frame and the mounting block of the present invention

FIG. 7 is a schematic view of the structural cooperation of the squeeze and lift assemblies of the present invention;

FIG. 8 is a schematic view of the structural fit between the first support frame and the base of the present invention;

FIG. 9 is a partial enlarged view of the structure at B in FIG. 8;

FIG. 10 is a schematic view of the internal structure of the pushing assembly of the present invention.

In the figure: 1. a first support frame; 2. a base; 3. connecting blocks; 4. a second support frame; 5. a sizing assembly; 51. a first rectangular block; 52. a limiting clamping groove; 53. a shaping bin body; 6. mounting blocks; 7. an extrusion assembly; 71. a second rectangular plate; 72. extruding the block; 73. a hydraulic cylinder; 74. a limiting column; 8. a lifting assembly; 81. a third rectangular plate; 82. lifting the block; 83. a limiting clamping block; 9. a servo motor; 10. a first bevel gear; 11. a first screw; 12. a second bevel gear; 13. a second screw; 14. a pushing assembly; 141. a pushing block; 142. a movable plate; 143. a telescopic rod; 144. and a slider.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1 to 10, the invention provides a shaping device for shale sintered hollow brick production, which comprises a first support frame 1 and a base 2 communicated with one side of the lower end of the first support frame 1, wherein the inner side of the top end of the first support frame 1 is fixedly connected with a connecting block 3 positioned above the base 2, the top of the connecting block 3 is fixedly connected with a second support frame 4, the inner part of the lower end of the second support frame 4 is fixedly connected with a shaping assembly 5, the front side and the rear side of the shaping assembly 5 are fixedly connected with mounting blocks 6, the bottom ends of the two mounting blocks 6 are fixedly connected with the base 2, the top end of the second support frame 4 is fixedly provided with an extrusion assembly 7, the bottom end of the extrusion assembly 7 penetrates through the second support frame 4 and extends into the second support frame 4, the inner part of the lower end of the shaping assembly 5 is movably sleeved with a lifting assembly 8, the back of the base 2 is fixedly provided with a servo motor 9, one end of an output shaft of the servo motor 9 is fixedly connected with a first bevel gear 10, the top of the first bevel gear 10 is fixedly connected with a first screw 11, and the top of the first screw 11 is in threaded sleeved with the lifting assembly 8.

As shown in fig. 4 and 7, the surface of the first bevel gear 10 is engaged with the second bevel gear 12, one side of the second bevel gear 12 away from the servo motor 9 is fixedly connected with the second screw 13, the surface of the second screw 13 is in threaded sleeve connection with the pushing assembly 14, the top end of the pushing assembly 14 is in sliding clamping connection with the connecting block 3, the shaping assembly 5 comprises a first rectangular block 51, the front surface and the back surface of the first rectangular block 51 are fixedly connected with the second support frame 4, both sides of the first rectangular block 51 are fixedly provided with limiting clamping grooves 52, the upper ends of both sides of the first rectangular block 51 are fixedly connected with the mounting block 6, five shaping bin bodies 53 are equidistantly arranged inside the top end of the first rectangular block 51, through the design of the second bevel gear 12, the second screw 13 and the pushing assembly 14, when the servo motor 9 starts to operate, the second bevel gear 12 is driven to rotate by the first bevel gear 10, the second bevel gear 12 drives the second screw 13 to move together, because the surface of the second screw 13 is in threaded sleeve connection with the pushing assembly 14, the top end of the pushing assembly 14 is slidably clamped inside the connecting block 3, the pushing assembly 14 is driven to move integrally, and the top of the hollow brick 5 is lifted and the hollow brick is lifted conveniently and moved on the top of the hollow brick 5; through first rectangle piece 51, spacing draw-in groove 52 and design of design storehouse body 53, because the design of five design storehouse bodies 53 will play spacing effect of stereotyping well to shale sintered hollow brick, and because design storehouse body 53 is inside to present for hollow form, after its inside at the design, the top to lifting subassembly 8 will be placed to the hollow brick, and then subsequent promotion collection processing has been facilitated by a wide margin, simultaneously because spacing draw-in groove 52's design will play spacing effect to follow-up lifting subassembly 8's activity.

As shown in fig. 7, the squeezing assembly 7 includes a second rectangular plate 71 and a hydraulic cylinder 73, the front and rear ends of both sides of the second rectangular plate 71 are movably connected to the second support frame 4 through sliders, five squeezing blocks 72 are fixedly mounted at equal intervals on the bottom of the second rectangular plate 71, a hydraulic cylinder 73 is fixedly mounted at the middle of the top end of the second support frame 4, the bottom of the hydraulic cylinder 73 penetrates through the second support frame 4 and extends into the second support frame 4 and is fixedly connected to the top of the second rectangular plate 71, two sides of the top of the second rectangular plate 71 are fixedly connected to limiting columns 74, the upper ends of the two limiting columns 74 penetrate through the second support frame 4 and extend above the second support frame 4 and are movably connected to the inner wall of the second support frame 4, through the design of the second rectangular plate 71, the squeezing blocks 72, the hydraulic cylinder 73 and the limiting columns 74, when the hydraulic cylinder 73 starts to operate, the hydraulic cylinder 73 drives the second rectangular plate 71 and the squeezing blocks 72 to move up and down, because of the matching design of the five squeezing blocks 72 will squeeze shale raw materials placed inside the sizing bin body 53, at this time, the two limiting columns 74 will play a role in guaranteeing stability of the second rectangular plate 71 when the limiting columns 74 move.

As shown in fig. 7, the lifting assembly 8 includes a third rectangular plate 81, the bottom of the third rectangular plate 81 is in threaded sleeve connection with the first screw 11, both sides of the third rectangular plate 81 are fixedly provided with limiting fixture blocks 83, the upper ends of the two limiting fixture blocks 83 are movably clamped inside the limiting fixture grooves 52, five lifting blocks 82 are fixedly mounted on the top of the third rectangular plate 81 at equal intervals, the upper ends of the five lifting blocks 82 are movably connected inside the shaping bin body 53, through the design of the third rectangular plate 81, the lifting blocks 82 and the limiting fixture blocks 83, when the first screw 11 drives the third rectangular plate 81 to move upwards, the shaping effect on the shale is realized due to the opposite movement of the lifting blocks 82 and the extrusion blocks 72, then the shale raw material after shaping is placed at the bottom of the lifting blocks 82, and when the first screw 11 drives the third rectangular plate 81 to move downwards, at this time, the bottom end of the third rectangular plate 81 is placed at the top of the base 2 due to the movement of the third rectangular plate 81, so as to further push the assembly 14 to push the shale to operate, and at the same time, the stability of the limiting fixture blocks 81 greatly improves the overall movement stability of the third rectangular plate 81.

As shown in fig. 10, the pushing assembly 14 includes a pushing block 141 and two sliding blocks 144, the pushing block 141 is disposed below the connecting block 3, the number of the sliding blocks 144 is two, the bottoms of the two sliding blocks 144 are both fixedly connected to the pushing block 141, the pushing block 141 is slidably connected to the connecting block 3 through the two sliding blocks 144, the bottom of the pushing block 141 is fixedly connected to a movable plate 142, the inner wall of the lower end of the movable plate 142 is in threaded socket with the surface of the second screw 13, a telescopic rod 143 is slidably connected to one side of the bottom of the pushing block 141 away from the movable plate 142, the inner wall of the lower end of the telescopic rod 143 is in movable socket with the surface of the second screw 13, through the design of the pushing block 141, the movable plate 142, the telescopic rod 143, and the sliding blocks 144, when the second screw 13 rotates, the movable plate 142 will drive the pushing block 141 and the sliding blocks 144 to move, because the design of the sliding blocks 144 will play a role in limiting the movement of the pushing block 141, when the pushing block 141 gradually starts to move, the inner side wall of the pushing block 141 will push the shale shaping material placed on the top of the lifting block 82 to slide into the top of the base 2, thereby achieving the collecting effect.

As shown in fig. 7, the area size of the inner cavity of the sizing bin body 53 is in adaptive connection with the area sizes of the surfaces of the extrusion block 72 and the lifting block 82, the inner cavity of the sizing bin body 53 is communicated with each other, and the inner wall of the sizing bin body 53 and the surfaces of the extrusion block 72 and the lifting block 82 are both smooth, through the design of the sizing bin body 53, when the lifting block 82 moves to the inside of the sizing bin body 53, a proper amount of shale raw material is poured into the limiting fixture block 83 at the moment, and meanwhile, the shale raw material placed at the top of the lifting block 82 is extruded due to the continuous descending of the extrusion block 72, so that the subsequent sizing effect is realized, and meanwhile, due to the area size of the inner cavity of the sizing bin body 53 and the adaptation of the sizes of the extrusion block 72 and the lifting block 82, and the smooth surfaces of the extrusion block 72 and the lifting block 82, the areas of the extrusion block 72 and the lifting block 82 move more smoothly in the inner cavity of the sizing bin body 53.

As shown in fig. 1, the base 2 is composed of an upper section and a lower section, the upper section of the base 2 is integrally in the form of an inclined plane and the width of the bottom end of the upper section is greater than that of the lower section of the base 2, the lower section of the base 2 is in the form of a rectangle and the lower end of the outer side wall of the lower section is fixedly connected with the first support frame 1, the inclined plane of the upper section of the base 2 is fixedly provided with a limit baffle, the hollow shale brick after shaping is successfully and downwards slid due to the design of the inclined plane at the top of the base 2, and further the hollow shale brick is conveniently and subsequently collected for use, and meanwhile, due to the design of the inclined plane surface limit baffle, the overall movable effect is greatly improved.

As shown in fig. 1 and 8, a side wall of the third rectangular plate 81 close to the base 2 is movably connected with the base 2, a side of a bottom end of the third rectangular plate 81 is movably connected with an outer end of an upper section of the base 2, a height value of the second support frame 4 is greater than a height value of the hydraulic cylinder 73 during lifting, through the design of the third rectangular plate 81, when the third rectangular plate 81 moves downwards, a side wall of the third rectangular plate 81 close to the base 2 will move downwards along an inner side wall of the base 2, when the third rectangular plate 81 descends to a certain extent, an upper end of the base 2 will act as a bottom stop for the third rectangular plate 81, so as to prevent the third rectangular plate 81 from continuing to move downwards, when the bottom end of the third rectangular plate 81 moves to an upper end of the base 2, the third rectangular plate 81 will drive the lifting block 82 to completely separate top-shaped shale from the inside of the shaped bin body 53, and then the shaped shale will pass through the base 2 due to pushing of the pushing block 141, so as to facilitate subsequent collection of the shale with the inclined surface outwards sliding; through the design of second support frame 4, when pneumatic cylinder 73 drove second rectangular plate 71 upward activity, owing to the restriction of second support frame 4 and pneumatic cylinder 73 height value this moment, can not cause the influence to the activity of second rectangular plate 71.

The working principle and the using process of the invention are as follows:

firstly, the third rectangular plate 81 drives the lifting block 82 to move to the inside of the shaping bin body 53 in an initial state, then shale is poured into the inside of the shaping bin body 53 by a worker, then the hydraulic cylinder 73 and the servo motor 9 are started, the hydraulic cylinder 73 is operated to drive the second rectangular plate 71 and the extrusion block 72 to move downwards together, and further the extrusion block 72 gradually moves to the inside of the shaping bin body 53, meanwhile, the servo motor 9 is operated to drive the first bevel gear 10 to drive the third rectangular plate 81 and the lifting block 82 to move upwards gradually through the first screw 11, and at the moment, the shale placed in the shaping bin body 53 is pressed and shaped up and down simultaneously due to the opposite movement of the lifting block 82 and the extrusion block 72, so that the extrusion force on shale is uniform, and the shaping effect on the shale is greatly improved;

subsequently, when the servo motor 9 rotates forward, the third rectangular plate 81 and the lifting block 82 are driven to move upward by the first bevel gear 10 and the first screw 11, at this time, due to the meshing relationship between the second bevel gear 12 and the first bevel gear 10, the second bevel gear 12 drives the movable plate 142, the pushing block 141, the telescopic rod 143 and the sliding block 144 to move outward together by the second screw 13, when the servo motor 9 rotates in reverse direction, the first bevel gear 10 drives the third rectangular plate 81 and the lifting block 82 to move downward together by the first screw 11, and drives the shale shaped at the top of the lifting block 82 to separate from the inside of the shaping bin body 53 together, at the same time, the second bevel gear 12 also drives the pushing block 141, the movable plate 142, the telescopic rod 143 and the sliding block 144 to move together to the lifting block 82 by the second screw 13, and as the pushing block 141 moves, when the third rectangular plate 81 is not in contact with the top of the base 2, the pushing block 141 lifts the shale placed at the top of the pushing block 82, so that the shale is lifted from the top of the base 2 to lift the telescopic rod 82, thereby facilitating the whole collection of the whole base 2.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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

Claims

1. The utility model provides a setting device is used in production of shale sintered hollow brick, includes first support frame (1) and base (2) with first support frame (1) lower extreme one side intercommunication, its characterized in that: the inner side of the top end of the first support frame (1) is fixedly connected with a connecting block (3) positioned above the base (2), the top of the connecting block (3) is fixedly connected with a second support frame (4), the inner part of the lower end of the second support frame (4) is fixedly connected with a shaping assembly (5), the front side and the rear side of the shaping assembly (5) are fixedly connected with mounting blocks (6), the bottom ends of the two mounting blocks (6) are fixedly connected with the base (2), the top end of the second support frame (4) is fixedly provided with an extrusion assembly (7), the bottom end of the extrusion assembly (7) penetrates through the second support frame (4) and extends into the second support frame (4), the inner part of the lower end of the shaping assembly (5) is movably sleeved with a lifting assembly (8), the back of the base (2) is fixedly provided with a servo motor (9), one end of an output shaft of the servo motor (9) is fixedly connected with a first bevel gear (10), the top of the first bevel gear (10) is fixedly connected with a first screw rod (11), and the top of the first screw rod (11) is in threaded connection with the lifting and sleeved with the lifting assembly (8);

the surface of the first bevel gear (10) is connected with a second bevel gear (12) in a meshed mode, one side, far away from the servo motor (9), of the second bevel gear (12) is fixedly connected with a second screw rod (13), the surface of the second screw rod (13) is in threaded sleeve connection with a pushing assembly (14), and the top end of the pushing assembly (14) is connected with the connecting block (3) in a sliding and clamping mode;

the pushing assembly (14) comprises two pushing blocks (141) and two sliding blocks (144), the pushing blocks (141) are arranged below the connecting block (3), the bottoms of the two sliding blocks (144) are fixedly connected with the pushing blocks (141), the pushing blocks (141) are slidably connected with the connecting block (3) through the two sliding blocks (144), a movable plate (142) is fixedly connected to the bottom of the pushing blocks (141), the inner wall of the lower end of the movable plate (142) is in threaded sleeve connection with the surface of the second screw (13), a telescopic rod (143) is slidably connected to one side, away from the movable plate (142), of the bottom of the pushing blocks (141), and the inner wall of the lower end of the telescopic rod (143) is in movable sleeve connection with the surface of the second screw (13);

the area size of the inner cavity of the sizing bin body (53) is in adaptive connection with the area sizes of the surfaces of the extrusion block (72) and the lifting block (82), the inner cavity of the sizing bin body (53) is communicated with each other, and the inner wall of the sizing bin body and the surfaces of the extrusion block (72) and the lifting block (82) are smooth;

one side wall that third rectangular plate (81) are close to base (2) and base (2) swing joint, one side and the outer end swing joint of base (2) upper segment part of third rectangular plate (81) bottom.

2. The setting device for shale sintered hollow brick production according to claim 1, characterized in that: design subassembly (5) includes first rectangle piece (51), the front and the back of first rectangle piece (51) all with second support frame (4) fixed connection, the equal fixed mounting in both sides of first rectangle piece (51) has spacing draw-in groove (52), the upper end of first rectangle piece (51) both sides all with installation piece (6) fixed connection, five design storehouse bodies (53) have been seted up to the inside equidistance on first rectangle piece (51) top.

3. The setting device for shale sintering hollow brick production according to claim 1, characterized in that: extrusion subassembly (7) include second rectangular plate (71) and pneumatic cylinder (73), both ends all pass through slider and second support frame (4) swing joint around second rectangular plate (71) both sides, the equidistant fixed mounting in bottom of second rectangular plate (71) has five extrusion pieces (72), the middle part fixed mounting on second support frame (4) top has pneumatic cylinder (73), the bottom of pneumatic cylinder (73) runs through second support frame (4) and extends to the inside of second support frame (4) and with the top fixed connection of second rectangular plate (71), the equal fixedly connected with in both sides at second rectangular plate (71) top has spacing post (74), two the upper end of spacing post (74) all runs through second support frame (4) and extends to the top of second support frame (4) and with the inner wall swing joint of second support frame (4).

4. The setting device for shale sintering hollow brick production according to claim 1, characterized in that: lifting subassembly (8) include third rectangular plate (81), the bottom and first screw rod (11) screw thread of third rectangular plate (81) cup joint, the equal fixed mounting in both sides of third rectangular plate (81) has spacing fixture block (83), two the equal activity joint in the inside of spacing draw-in groove (52) in upper end of spacing fixture block (83), the top equidistance fixed mounting of third rectangular plate (81) has five lifting pieces (82), five the equal swing joint in the inside of design storehouse body (53) in upper end of lifting piece (82).

5. The setting device for shale sintered hollow brick production according to claim 1, characterized in that: the base (2) is composed of an upper section part and a lower section part, the upper section part of the base (2) is integrally in an inclined plane shape, the width value of the bottom end of the upper section part is larger than that of the lower section part of the base (2), the lower section part of the base (2) is in a rectangular shape, the lower end of the outer side wall of the lower section part of the base is fixedly connected with the first support frame (1), and a limit baffle is fixedly installed at the inclined plane of the upper section part of the base (2).

6. The setting device for shale sintered hollow brick production according to claim 1, characterized in that: the height value of the second support frame (4) is greater than the lifting height value of the hydraulic cylinder (73).