CN113815089A

CN113815089A - Evaporate and press aerated concrete slab production facility

Info

Publication number: CN113815089A
Application number: CN202110944638.0A
Authority: CN
Inventors: 解正祥
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-08-17
Filing date: 2021-08-17
Publication date: 2021-12-21

Abstract

The invention discloses autoclaved aerated concrete slab production equipment, which relates to the field of concrete slab production and comprises a base, wherein sealing boxes are welded on two sides of the top of the base, a workbench is arranged on the top of each sealing box, a fixed block is welded on the left side of the top of the workbench, a driving motor is fixedly connected to the top of each fixed block, two inclined steel plates are welded on the top of the workbench, a stirring cylinder body is sleeved inside each inclined steel plate, and a diversion trench is fixedly connected to the right side of the top of the workbench. Inside the raw materials pours into the stirring cylinder body through the inlet pipe, behind switch-on driving motor's external power supply, driving motor's output orders about the transmission axle and rotates, forces the second gear to drive the first gear rotation of both sides after the transmission axle rotates, so first gear is with pivot one positive and negative rotation, so the inside raw materials of stirring cylinder body is ordered about the spiral twisted sheet in the pivot and is rotated down by intensive mixing.

Description

Evaporate and press aerated concrete slab production facility

Technical Field

The invention relates to the field of concrete slab production, in particular to autoclaved aerated concrete slab production equipment.

Background

The autoclaved aerated concrete slab is a lightweight porous novel green environment-friendly building material which takes cement, lime, silica sand and the like as main raw materials, is added with different quantities of steel bar meshes subjected to corrosion protection treatment according to structural requirements, is cured at high temperature and high pressure by steam, and reacts to produce the autoclaved aerated concrete slab with porous crystals, has lower density than common cement materials, and has excellent properties of fire resistance, fire prevention, sound insulation, heat preservation and the like which are not unique.

The existing stage manufacturing equipment cannot fully stir the raw materials of the concrete, so that the concentration and the density of the concrete cannot meet the requirements, and therefore an autoclaved aerated concrete slab production equipment is provided.

Disclosure of Invention

In order to solve the technical problems in the background art, the invention provides the autoclaved aerated concrete slab production equipment which is ingenious in structure and reasonable in design, solves the problem of insufficient stirring in the processes of stirring and screening concrete raw materials, simultaneously carries out vibration and tamping on the concrete, and simultaneously carries out air entrainment on the concrete, so that the strength of the concrete is improved, the lightweight of the concrete is guaranteed, the operation is simple, the use is convenient, the practicability is strong, and the autoclaved aerated concrete slab production equipment is suitable for wide popularization.

The invention provides autoclaved aerated concrete slab production equipment which comprises a base (1), wherein sealing box bodies (6) are welded on two sides of the top of the base (1), a workbench (17) is arranged on the top of each sealing box body (6), a fixed block (16) is welded on the left side of the top of the workbench (17), a driving motor (15) is fixedly connected to the top of each fixed block (16), two inclined steel plates (13) are welded on the top of the workbench (17), a stirring cylinder body (11) is sleeved inside each inclined steel plate (13), and a diversion trench (8) is fixedly connected to the right side of the top of the workbench (17);

the stirring cylinder is characterized in that a net-shaped isolation plate (38) is arranged in the stirring cylinder body (11), a transmission shaft (14) penetrating through and extending into the stirring cylinder body (11) is welded at the output end of the driving motor (15), a second gear (29) is welded at one end of the transmission shaft (14) located in the stirring cylinder body (11), two rotating shafts (10) are rotatably connected between the inner wall of one side of the stirring cylinder body (11) and the isolation net (38), a spiral twisted piece (12) is welded at the outer ring of each rotating shaft (10), a first gear (28) is welded at the left side of the outer ring of each rotating shaft (10), the first gear (28) is meshed with the second gear (29) and connected with each other, one rotating shaft (10) penetrates through the isolation net (38) to be connected with a third gear (41), a feeding hole (44) is formed in the stirring cylinder body (11) on one side of the isolation net, and an annular groove is formed in the inner wall of the stirring cylinder body (11) on the other side of the isolation net (38), be equipped with in the ring channel and be equipped with rotating tube (39), rotating tube (39) inner wall is equipped with ring gear (40) and stirs board (42), third gear (41) and ring gear (40) meshing, the stirring cylinder body (11) of separation net (38) opposite side still are equipped with the discharge gate, discharge gate (9) correspond in guiding gutter (8) top, stirring cylinder body (11) inner wall is equipped with honeycomb duct (43) intercommunication discharge gate (9), and the honeycomb duct is half-cylinder body structure, and the opening up corresponds in stirring board (42) below.

The further technology of the invention is as follows:

preferably, the inner wall of the bottom of the sealing box body (6) is fixedly connected with a gas tank (7), the output end of the gas tank (7) is fixedly connected with a gas pipe (5) which penetrates through and extends to the outside of the sealing box body (6), the first shell (4) is sleeved at one end of the gas pipe (5) which is positioned outside the sealing box body (6), the frame (2) is welded at the top of the base (1), the oil hydraulic cylinder (21) is fixedly connected with the inner wall of the back of the frame (2), the hydraulic rod (22) is fixedly connected with the front of the oil hydraulic cylinder (21), the fixture block (23) is welded at one end of the hydraulic rod (22), the movable plate (3) is clamped at one side of the fixture block (23) far away from the hydraulic rod (22), the balance rods (25) are welded at two sides of the movable plate (3), and two first springs (27) are welded at one side of the movable plate (3) far away from the fixture block (23), one end of the first spring (27) far away from the movable plate (3) is welded with the front inner wall of the frame (2), sliding rails (24) are welded on two sides of the front inner wall of the frame (2), and sliding blocks (26) are connected to the tops of the sliding rails (24) in a sliding mode.

Preferably, the top welding of fly leaf (3) has second casing (18), the one end that gas-supply pipe (5) are located first casing (4) runs through and extends to in second casing (18), the one end that gas-supply pipe (5) are located second casing (18) has all cup jointed coiled pipe (20), the bottom of coiled pipe (20) and the bottom inner wall fixed connection of second casing (18), the top evenly distributed of coiled pipe (20) has a plurality of scattered gas pockets, coiled pipe (20) are the flat state.

Preferably, the inner wall of the first shell (4) is welded with a box body (31), the inner wall of one side of the box body (31) close to the first shell (4) is welded with two second springs (30), one ends of the second springs (30) close to each other are welded with sliding plates (32) in sliding connection with the inner walls of two sides of the box body (31), one side of each sliding plate (32) far away from the second spring (30) is welded with two fixing rods (36) penetrating and extending out of the box body (31), one ends of the fixing rods (36) located outside the box body (31) are welded with connecting blocks (34), one side of each connecting block (34) far away from the fixing rods (36) is welded with the outer side of the second shell (18), one side of each connecting block (34) far away from the second shell (18) is welded with buffer springs (35) sleeved on the outer rings of the fixing rods (36), the middle part of one side of each connecting block (34) far away from the second shell (18) is welded with movable columns (33) penetrating and extending into the box body (31), one end of the movable column (33) positioned in the box body (31) is welded with the middle part of one side of the sliding plate (32) far away from the second spring (30).

Preferably, sliding grooves are formed in the inner walls of the two sides of the box body (31), sliding plates are sleeved in the sliding grooves, two ends of each sliding plate (32) are welded to one end, close to each other, of each sliding plate, and the cross sections of the sliding grooves are T-shaped.

Preferably, first through-hole has been seted up to the both sides of first casing (4), all cup jointed sealing washer (19) in the first through-hole, the outer lane of sealing washer (19) inner wall and gas-supply pipe (5) cup joints, discharging pipe (9) have been cup jointed on the right side of stirring cylinder body (11), the inlet pipe has been cup jointed at the top of stirring cylinder body (11).

Firstly, pouring a mixed liquid raw material of a concrete raw material, lime and the like into a stirring cylinder body (11) through a feeding pipe, after an external power supply of a driving motor (15) is connected, driving an output end of the driving motor (15) to drive a transmission shaft (14) to rotate, driving a second gear (29) to drive first gears (28) at two sides to rotate after the transmission shaft (14) rotates, then the first gears (28) rotate a rotating shaft (10) in a forward and reverse direction, so that the raw material in the stirring cylinder body (11) is fully and uniformly stirred under the rotation of a spiral twisting sheet (12) driven by the rotating shaft (10), meanwhile, the spiral direction of the spiral twisting sheet (12) rotates towards the inclination direction of the stirring cylinder body (11), so that the raw material is forced to stir upwards while stirring to form a reciprocating stirring action on the raw material, the stirred raw material enters the other side of an isolation net and the other side of the isolation net through the isolation net, the rotating shaft (10) drives the third gear (41) to rotate, the third gear (41) drives the rotating pipe (39) to rotate, and in the rotating process of the rotating pipe (39), the stirring plate (42) drives the raw materials to stir, and meanwhile, the raw materials are driven to rise and flow out of the discharge hole in the flow guide pipe (43) to a high position.

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

1. the device is through installing stirring cylinder body, inlet pipe isotructure, wherein inside the stirring cylinder body is emptyd into through the inlet pipe at the raw materials, behind switch-on driving motor's external power supply, driving motor's output orders about the transmission axle and rotates, forces the first gear rotation of second gear drive both sides after the transmission axle rotates, so first gear is with a rotation of pivot positive and negative rotation, so the inside raw materials of stirring cylinder body order about the spiral twisted piece in the pivot and rotate down by intensive mixing.

2. The device stirring cylinder body slope, utilize spiral twisted sheet to drive the raw materials and be forced upwards to mix when the stirring, form the reciprocal stirring action to the raw materials, but the residue of the interior raw materials of cylinder body that the stirring cylinder body that has the slope equally brought, the raw materials after the stirring gets into the separation net opposite side through the separation net, in the opposite side, the pivot drives the third gear and rotates, the third gear drives the rotating tube and rotates, the rotating tube pivoted in-process, the stirring board moves the raw materials and stirs, and simultaneously, the raw materials that drives stirring cylinder body bottom rises, flow from the discharge gate in falling into the draft tube to high department, reduce the raw materials residue of stirring cylinder body bottom.

3. The device is through installing spiral skein piece isotructure, wherein the screw direction of spiral skein piece is for the direction rotation to the stirring cylinder body slope, so the raw materials is forced upwards to stir in the stirring, form the reciprocal stirring action to the raw materials, so obtain abundant stirring and stir the bits of broken glass at the inside raw materials of stirring cylinder body, and then carried out a screening to impurity in the raw materials and ups and downs, has not only guaranteed the purity of raw materials, has ensured concrete slab's rigidity and toughness simultaneously effectively.

4. The device is through installing the guiding gutter isotructure, wherein the concrete fluid passes through on the reason of gravity flows to the guiding gutter from the discharging pipe, and the tilt state and the smooth surface of guiding gutter provide strong guarantee for the concrete refluence after the stirring, under the drainage effect of guiding gutter, the concrete fluid passes through natural flow when flowing on the guiding gutter, natural air-drying to a certain extent of concrete fluid has been impeld, and after the concrete fluid is guided to first casing inside by the guiding gutter, the effect of gravity makes the inseparable degree of concrete fluid improve to some extent.

5. The device is through installing gas pitcher, coiled pipe isotructure, wherein after the inside of concrete entering first casing, the inside atmospheric pressure of gas pitcher is irritated the concrete, and the coiled pipe is arranged in the bottom of concrete simultaneously, so after the gas pore pair concrete that looses on the coiled pipe was irritated the gas, the gas receiving point of concrete was arranged unanimously, can not lead to because the uneven phenomenon that rises that leads to of distribution of gas, has realized the slight change to the concrete simultaneously.

6. The device is through installing the oil hydraulic cylinder, fixture block isotructure, wherein the oil hydraulic cylinder orders about the hydraulic stem and applys thrust to the fixture block, and the fixture block will promote the fly leaf and shake to the first casing at fly leaf top, and the elasticity of first spring makes the resilience of fly leaf quicker, it is more regular to shake, the too big state to the concrete fluid of thrust for avoiding the oil hydraulic cylinder causes destruction, after the thrust of oil hydraulic cylinder is too big, the vibration range of second casing is too big so the connecting block receives the swing extrusion of second casing, cushion spring is given through the conduction range and cushions, then movable post and dead lever are to the inside shrink of box, the second spring at this moment is compressed, and the elasticity of second spring and buffer spring makes the swing range of second casing receive control.

To sum up, the device structure is ingenious, and reasonable in design has not only solved the not abundant problem of stirring in stirring, the screening procedure to the concrete raw materials, vibrates the tamp to the concrete simultaneously, carries out the air entrainment to the concrete simultaneously, has not only promoted the intensity of concrete, has guaranteed the lightweight of concrete simultaneously, easy operation, convenient to use, and the practicality is strong simultaneously, is fit for extensively promoting.

Drawings

Fig. 1 is a schematic front structural view of an autoclaved aerated concrete slab production device provided by the invention.

Fig. 2 is a schematic top view of a serpentine pipe of an autoclaved aerated concrete slab production facility according to the present invention.

Fig. 3 is a schematic top view of a movable plate of an autoclaved aerated concrete slab production facility according to the present invention.

Fig. 4 is a schematic diagram of the internal structure of a stirring cylinder body of the autoclaved aerated concrete slab production equipment provided by the invention.

Fig. 5 is a partial enlarged structural schematic view of a part B of an autoclaved aerated concrete slab production device provided by the invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings in conjunction with the following detailed description. It should be understood that the description is intended to be exemplary only, and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

Example 1: the invention provides autoclaved aerated concrete slab production equipment which comprises a base 1 and is characterized in that sealing box bodies 6 are welded on two sides of the top of the base 1, a workbench 17 is arranged on the top of each sealing box body 6, a fixed block 16 is welded on the left side of the top of the workbench 17, a driving motor 15 is fixedly connected to the top of each fixed block 16, two inclined steel plates 13 are welded on the top of each workbench 17, a stirring cylinder body 11 is sleeved inside each inclined steel plate 13, and a diversion trench 8 is fixedly connected to the right side of the top of each workbench 17;

a reticular isolation plate 38 is arranged in the stirring cylinder body 11, a transmission shaft 14 penetrating through and extending into the stirring cylinder body 11 is welded at the output end of the driving motor 15, a second gear 29 is welded at one end of the transmission shaft 14 positioned in the stirring cylinder body 11, two rotating shafts 10 are rotatably connected between the inner wall of one side of the stirring cylinder body 11 and the isolation net 38, a spiral twisted piece 12 is welded on the outer ring of the rotating shaft 10, a first gear 28 is welded on the left side of the outer ring of the rotating shaft 10, the first gear 28 and the second gear 29 are mutually meshed and connected, one rotating shaft 10 penetrates through the isolation net 38 to be connected with a third gear 41, a feeding hole 44 is arranged on the stirring cylinder body 11 on one side of the isolation net, an annular groove is arranged on the inner wall of the stirring cylinder body 11 on the other side of the isolation net 38, a rotating pipe 39 is arranged in the annular groove, and a gear ring 40 and a stirring plate 42 are arranged on the inner wall of the rotating pipe 39, the third gear 41 is meshed with the gear ring 40, the stirring cylinder body 11 on the other side of the separation net 38 is further provided with a discharge hole, the discharge hole 9 corresponds to the upper side of the diversion trench 8, the inner wall of the stirring cylinder body 11 is provided with a diversion pipe 43 communicated with the discharge hole 9, the diversion pipe is of a semi-cylindrical pipe structure and is upwardly opened and corresponds to the lower side of the stirring plate 42.

Example 2: the bottom inner wall of the sealing box body 6 is fixedly connected with a gas tank 7, the output end of the gas tank 7 is fixedly connected with a gas pipe 5 which penetrates through and extends out of the sealing box body 6, one end of the gas pipe 5, which is positioned out of the sealing box body 6, is sleeved with a first shell 4, the top of the base 1 is welded with a frame 2, the back inner wall of the frame 2 is fixedly connected with an oil hydraulic cylinder 21, the front of the oil hydraulic cylinder 21 is fixedly connected with a hydraulic rod 22, one end of the hydraulic rod 22, which is away from the oil hydraulic cylinder 21, is welded with a fixture block 23, one side of the fixture block 23, which is away from the hydraulic rod 22, is clamped with a movable plate 3, two sides of the movable plate 3 are welded with balance rods 25, one side of the movable plate 3, which is away from the fixture block 23, is welded with two first springs 27, one end of the first springs 27, which is away from the movable plate 3, is welded with the front inner wall of the frame 2, and slide rails 24 are welded on two sides of the front inner wall of the frame 2, a sliding block 26 is slidably connected to the top of the sliding rail 24. First through-hole has been seted up to the both sides of first casing 4, all cup jointed sealing washer 19 in the first through-hole, the outer lane of sealing washer 19 inner wall and gas-supply pipe 5 cup joints, discharging pipe 9 has been cup jointed on the right side of stirring cylinder body 11, the inlet pipe has been cup jointed at the top of stirring cylinder body 11.

Example 3: the welding of the top of fly leaf 3 has second casing 18, the one end that the gas-supply pipe 5 is located first casing 4 runs through and extends to in the second casing 18, the one end that the gas-supply pipe 5 is located second casing 18 has all cup jointed coiled pipe 20, the bottom of coiled pipe 20 and the bottom inner wall fixed connection of second casing 18, the top evenly distributed of coiled pipe 20 has a plurality of scattered gas pockets, coiled pipe 20 is the flat state.

Example 4: the inner wall of first casing 4 all welds box 31, box 31 has two second springs 30 near the welding of one side inner wall of first casing 4, the one end welding that second spring 30 is close to each other has the sliding plate 32 with the both sides inner wall sliding connection of box 31, the welding of one side that second spring 30 was kept away from to sliding plate 32 has two dead levers 36 that run through and extend to the box 31 outside, dead lever 36 is located the welding of the outer one end of box 31 has connecting block 34, the outside welding of one side and second casing 18 that dead lever 36 was kept away from to connecting block 34, the welding of one side that second casing 18 was kept away from to connecting block 34 has buffer spring 35 that cup joints in the dead lever 36 outer lane, the welding of one side middle part that second casing 18 was kept away from to connecting block 34 has movable post 33 that runs through and extend to the box 31, the one side middle part welding that second spring 30 was kept away from to movable post 33 is located box 31 and sliding plate 32. The inner walls of the two sides of the box body 31 are provided with sliding grooves, sliding plates are sleeved in the sliding grooves, two ends of each sliding plate 32 are welded with one ends, close to the sliding plates, of the sliding plates, and the cross sections of the sliding grooves are T-shaped.

Example 5: the spout has been seted up to the both sides inner wall of box 31, the slide has been cup jointed in the spout, the both ends of sliding plate 32 and the one end welding that the slide is close to each other, the cross section of spout is the T type, first gear 28 is connected with 29 intermeshing of second gear, the diameter of first gear 28 is less than the diameter of second gear 29, first through-hole has been seted up to the both sides of first casing 4, all cup jointed sealing washer 19 in the first through-hole, the outer lane of sealing washer 19 inner wall and gas-supply pipe 5 cup joints, discharging pipe 9 has been cup jointed on the right side of stirring cylinder body 11, the inlet pipe has been cup jointed at the top of stirring cylinder body 11.

In the invention, firstly, the mixed liquid raw material of concrete raw material and lime, etc. is poured into the interior of the mixing cylinder body 11 through the feeding pipe, after the external power supply of the driving motor 15 is connected, the output end of the driving motor 15 drives the transmission shaft 14 to rotate, the transmission shaft 14 rotates to force the second gear 29 to drive the first gears 28 at two sides to rotate, so that the first gears 28 rotate the rotating shaft 10 in the positive and negative directions, so that the raw material in the interior of the mixing cylinder body 11 is fully and uniformly mixed under the rotation of the rotating shaft 10 driving the spiral twisted piece 12, meanwhile, the spiral direction of the spiral twisted piece 12 is the direction inclined to the mixing cylinder body 11, so that the raw material is forced to be stirred upwards while being mixed, so as to form the reciprocating mixing action of the raw material, the mixed raw material enters the other side of the separation net through the separation net, in the other side, the rotating shaft 10 drives the third gear 41 to rotate, the third gear 41 drives the rotating pipe 39 to rotate, in the process of rotating the rotating pipe 39, the stirring plate 42 drives the raw material to stir, and at the same time, drives the raw material to rise and fall into the guide pipe 43 to the high position and flow out from the discharge port.

The raw materials after the stirring in the stirring cylinder body 11 are gradually changed into thin fluid, and the thin fluid flows to the diversion trench 8 from the discharge pipe 9 due to the gravity, the inclined state and the smooth surface of the diversion trench 8 provide a powerful guarantee for the backflow of the uniformly stirred concrete, under the drainage action of the diversion trench 8, the concrete fluid flows on the diversion trench 8 and naturally flows, so that the natural air drying of the concrete fluid to a certain extent is promoted, and after the concrete fluid is guided to the inside of the first shell 4 by the diversion trench 8, the tightness of the concrete fluid is improved by the gravity;

after entering the first shell 4, the gas in the gas tank 7 is uniformly distributed at the bottom of the first shell 4 through the gas conveying pipe 5 and is uniformly and orderly poured into the concrete fluid, after the concrete enters the first shell 4, the concrete is filled by the gas pressure in the gas tank 7, meanwhile, the coiled pipe 20 is distributed at the bottom of the concrete, so that after the gas is filled into the concrete through the gas dispersing holes in the coiled pipe 20, the distribution of the gas bearing points of the concrete is consistent, the explosion phenomenon caused by the uneven distribution of the gas cannot be caused, and the concrete is lightened;

meanwhile, after the interior of the first housing 4 is filled with concrete, the hydraulic cylinder 21 drives the hydraulic rod 22 to apply a thrust to the fixture block 23, the fixture block 23 pushes the movable plate 3 to vibrate the first housing 4 on the top of the movable plate 3, and the sliding of the sliding rail 24 and the slider 26 makes the reciprocating motion of the movable plate 3 smoother, so that the vibration efficiency is more effective, and the elasticity of the first spring 27 makes the rebound of the movable plate 3 faster, and the vibration is more regular, so as to avoid the damage to the concrete fluid state caused by the excessive thrust of the hydraulic cylinder 21, when the thrust of the hydraulic cylinder 21 is too large, the vibration amplitude of the second housing 18 is too large, so that the connecting block 34 is pressed by the swing of the second housing 18, the buffer spring 35 is buffered by the conduction amplitude, and then the movable column 33 and the fixed rod 36 contract towards the interior of the housing 31, the second spring 30 is compressed, and the elasticity of the second spring 30 and the buffer spring 35 makes the swing amplitude of the second housing 18 controlled.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such changes and modifications that fall within the scope and bounds of the appended claims, or equivalents of such scope and bounds.

Claims

1. The autoclaved aerated concrete slab production equipment comprises a base (1) and is characterized in that sealing boxes (6) are welded on two sides of the top of the base (1), a workbench (17) is arranged on the top of each sealing box (6), a fixed block (16) is welded on the left side of the top of each workbench (17), a driving motor (15) is fixedly connected to the top of each fixed block (16), two inclined steel plates (13) are welded on the top of each workbench (17), a stirring cylinder body (11) is sleeved inside each inclined steel plate (13), and a diversion trench (8) is fixedly connected to the right side of the top of each workbench (17);

2. The autoclaved aerated concrete slab production equipment according to claim 1, wherein a gas tank (7) is fixedly connected to the bottom inner wall of the seal box body (6), a gas pipe (5) penetrating and extending out of the seal box body (6) is fixedly connected to the output end of the gas tank (7), a first shell (4) is sleeved at one end of the gas pipe (5) positioned outside the seal box body (6), a frame (2) is welded at the top of the base (1), an oil hydraulic cylinder (21) is fixedly connected to the back inner wall of the frame (2), a hydraulic rod (22) is fixedly connected to the front of the oil hydraulic cylinder (21), a clamping block (23) is welded at one end of the hydraulic rod (22) far away from the oil hydraulic cylinder (21), a movable plate (3) is clamped at one side of the clamping block (23) far away from the hydraulic rod (22), and balance rods (25) are welded at two sides of the movable plate (3), one side welding that fixture block (23) were kept away from in fly leaf (3) has two first springs (27), the one end that fly leaf (3) were kept away from in first spring (27) and the front inner wall welding of frame (2), slide rail (24) have all been welded to the front inner wall both sides of frame (2), the top sliding connection of slide rail (24) has slider (26).

3. The autoclaved aerated concrete panel production equipment according to claim 2, wherein a second shell (18) is welded on the top of the movable plate (3), one end of the gas pipe (5) in the first shell (4) penetrates and extends into the second shell (18), one end of the gas pipe (5) in the second shell (18) is sleeved with a coiled pipe (20), the bottom of the coiled pipe (20) is fixedly connected with the inner wall of the bottom of the second shell (18), a plurality of air dispersion holes are uniformly distributed on the top of the coiled pipe (20), and the coiled pipe (20) is in a flat state.

4. The autoclaved aerated concrete panel production equipment according to claim 1, wherein the inner wall of the first shell (4) is welded with a box body (31), the inner wall of one side of the box body (31) close to the first shell (4) is welded with two second springs (30), the ends of the second springs (30) close to each other are welded with sliding plates (32) slidably connected with the inner walls of the two sides of the box body (31), one side of the sliding plates (32) far away from the second springs (30) is welded with two fixing rods (36) penetrating and extending out of the box body (31), the end of the fixing rod (36) located outside the box body (31) is welded with a connecting block (34), one side of the connecting block (34) far away from the fixing rods (36) is welded with the outer side of the second shell (18), one side of the connecting block (34) far away from the second shell (18) is welded with a buffer spring (35) sleeved on the outer ring of the fixing rod (36), the middle part of one side of the connecting block (34) far away from the second shell (18) is welded with a movable column (33) which penetrates through and extends into the box body (31), and one end of the movable column (33) in the box body (31) is welded with the middle part of one side of the sliding plate (32) far away from the second spring (30).

5. The autoclaved aerated concrete panel production equipment according to claim 4, wherein sliding grooves are formed in the inner walls of the two sides of the box body (31), sliding plates are sleeved in the sliding grooves, the two ends of the sliding plate (32) are welded with one ends of the sliding plates close to each other, and the cross section of the sliding grooves is T-shaped.

6. The autoclaved aerated concrete panel production equipment according to claim 2, wherein first through holes are formed in two sides of the first shell (4), sealing rings (19) are sleeved in the first through holes, the inner walls of the sealing rings (19) are sleeved with the outer rings of the gas pipes (5), a discharge pipe (9) is sleeved on the right side of the stirring cylinder body (11), and a feed pipe is sleeved on the top of the stirring cylinder body (11).

7. The autoclaved aerated concrete panel production equipment according to claim 1, wherein the liquid raw material mixed with concrete raw material and lime is poured into the interior of the mixing cylinder (11) through the feeding pipe, after the external power supply of the driving motor (15) is connected, the output end of the driving motor (15) drives the transmission shaft (14) to rotate, the second gear (29) is forced to drive the first gears (28) at both sides to rotate after the transmission shaft (14) rotates, so that the first gears (28) rotate the rotating shaft (10) in a forward and reverse direction, so that the raw material in the interior of the mixing cylinder (11) is fully and uniformly mixed under the rotation of the spiral twisting sheet (12) driven by the rotating shaft (10), and the spiral direction of the spiral twisting sheet (12) is in a direction inclined to the mixing cylinder (11), so that the raw material is forced to stir upwards while stirring, thereby forming a reciprocating stirring action to the raw material, the stirred raw materials enter the other side of the separation net through the separation net, in the other side, the rotating shaft (10) drives the third gear (41) to rotate, the third gear (41) drives the rotating pipe (39) to rotate, in the rotating process of the rotating pipe (39), the stirring plate (42) drives the raw materials to stir, and meanwhile, the raw materials are driven to rise to the high position and fall into the guide pipe (43) to flow out of the discharge hole.