CN114852527A

CN114852527A - Magnesite building materials production strorage device

Info

Publication number: CN114852527A
Application number: CN202210538882.1A
Authority: CN
Inventors: 杨文海
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-05-17
Filing date: 2022-05-17
Publication date: 2022-08-05

Abstract

The invention discloses a magnesite building material production and storage device which comprises a top fixing plate and a bottom fixing plate, wherein the top fixing plate and the bottom fixing plate are arranged on the upper side and the lower side of a magnesite board and are fixed on a rear support and a front support which are vertically arranged, sliding detection probes for detecting the upper surface and the lower surface of the magnesite board are arranged between the adjacent rear support and the front support, and roller grooves are formed in the top of the top fixing plate and the bottom of the bottom fixing plate. The invention adopts the sliding detection probes for detecting the upper surface and the lower surface of the magnesite boards between the adjacent rear support and the front support, and it needs to be explained that the sliding detection probes are connected through a network at the moment, and the sliding detection probes upload the surface condition pictures between the two adjacent magnesite boards to a 5G network in real time in the process of sliding up and down, thereby being convenient for real-time detection and observation and timely making a response.

Description

Magnesite building materials production strorage device

Technical Field

The invention relates to the technical field of production management, in particular to a magnesite building material production and storage device.

Background

At present, the building material production management process is more and more dependent on the supervision of a 5G network, so that manual inspection can be effectively replaced, and the problem that accidents happen when people shift or unattended time happens can be solved.

The production management process of the magnesite building materials needs to pay extra attention to the surfaces of the corresponding magnesite boards, the stacked magnesite boards have places which cannot be seen by people due to angle problems, corresponding frosting and sweating phenomena can occur in the places, if magnesium oxide crystals are not processed in time, magnesium oxide can chemically react with water vapor in the air to generate magnesium hydroxide, and the magnesium hydroxide can further react with carbon dioxide to finally become magnesium carbonate attached to the surfaces of the magnesite building materials, so that frosting is achieved; the magnesite building materials have high magnesium chloride content and absorb water, which is often called sweat, so that a 5G network management system for managing and maintaining the surfaces of the magnesite building materials is needed urgently.

Therefore, a magnesite building material production and storage device is designed.

Disclosure of Invention

The invention aims to solve the problems of 'frosting' and 'sweating' on the surface of a magnesite building material which cannot be seen by people due to the angle problem, and provides a magnesite building material production and storage device.

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

a magnesite building material production and storage device comprises a top fixing plate and a bottom fixing plate which are arranged on the upper side and the lower side of a magnesite board, wherein the top fixing plate and the bottom fixing plate are fixed on a rear support and a front support which are vertically arranged, a sliding detection probe for detecting the upper surface and the lower surface of the magnesite board is arranged between the rear support and the front support, the top fixing plate and the bottom fixing plate are respectively provided with a roller groove, sliding cleaning plates tightly attached to the surface of the magnesite board slide are arranged on the top fixing plate and the bottom fixing plate, the sliding cleaning plates roll in the roller grooves through rollers arranged on the two sides, the rollers are rotatably connected with the sliding cleaning plates through driving shafts penetrating through the sliding cleaning plates, driving motors for driving are arranged on the driving shafts, a water suction cavity and an air injection cavity are arranged in the sliding cleaning plates, and are separated by partition plates, first sliding tray has been seted up to the division board bottom, and slides in the first sliding tray and have the L shaped plate, absorb water the intracavity and be equipped with the sponge that absorbs water that is used for absorbing moisture, and absorb water the sponge tip and be equipped with the wringing board that is used for the sponge that absorbs water of extrusion, the wringing board links to each other with the L shaped plate, the wringing board links to each other with the clean board of slip through the collection device that draws water, be equipped with one-way air jet device in the jet-propelled chamber, the top of top fixed plate and the bottom of bottom fixed plate are equipped with gas holder and lower gas holder respectively, it has oxygen and helium to go up the gas holder and store respectively in the gas holder down, the clean board that slides links to each other with last gas holder and lower gas holder respectively through rubber hose, the cover is equipped with actuating mechanism that resets on the drive shaft.

Preferably, the side wall of the roller is provided with a plurality of magnet lugs, and the bottom of the roller groove is provided with a magnet groove matched with the magnet lugs on the side wall of the roller.

Preferably, the water pumping and collecting device comprises a plurality of water suction holes, a buffer spring, a sliding cavity, a first hollow pipe, a second hollow pipe, a first water inlet valve, a second water inlet valve, a water flowing pipe, a water storage cavity and a rotating cover, wherein the water suction holes are formed in the water squeezing plate and face the water absorbing sponge, the sliding cavity is formed in the side wall of the water suction cavity, the water squeezing plate slides in the sliding cavity through the first hollow pipe, the water suction holes are communicated with the first hollow pipe, the second water inlet valve is arranged in each water suction hole, one end of the second hollow pipe slides in the first hollow pipe through the first water inlet valve, the other end of the second hollow pipe is fixed to one side of the sliding cavity, the second hollow pipe is communicated with the water storage cavity through the water flowing pipe, and the bottom of the water storage cavity is provided with the rotating cover for sealing.

Preferably, the water absorption sponge is tightly attached to the surface of the magnesite board, and the bottom of the rotating cover is higher than the bottom of the water absorption sponge.

Preferably, the first water inlet valve and the second water inlet valve are both one-way valves, the flow direction of the water flow of the first water inlet valve faces the first hollow pipe, and the flow direction of the water flow of the second water inlet valve faces the second hollow pipe.

Preferably, one-way air jet system includes jet-propelled pipe, intake pipe, preceding barrier ring, motion piston, back barrier ring, elasticity stay cord and outlet duct, the intake pipe links to each other with rubber hose, the intake pipe communicates with jet-propelled pipe, preceding barrier ring and back barrier ring are located intake pipe and jet-propelled pipe intercommunication point both sides respectively, the motion piston is located between preceding barrier ring and the back barrier ring, the motion piston passes through the elasticity stay cord and stretches, back barrier ring is provided with a plurality of second reset spring towards motion piston one side.

Preferably, the reset driving mechanism comprises a rotary take-up reel, a telescopic block, a spiral groove, a fixed block, a second sliding groove, a convex block, a rotary curved rod, a baffle, a winding rope and a first reset spring, the rotary take-up reel rotates on the driving shaft through the telescopic block, the telescopic block rotates on the sliding cleaning plate through the first return spring, the rotary take-up reel and the telescopic block slide through the fixed block and the second sliding groove which are arranged in the circumference, the spiral block is circumferentially arranged on the surface of the driving shaft, the spiral groove is arranged on the inner wall of the telescopic block, and the spiral groove is matched with the spiral block, one end of the rotating curved rod rotates on the rotating take-up reel through the convex block, the other end of the rotating curved rod is rotatably connected with the L-shaped plate through a pillow block, the baffle is arranged on a rotating take-up reel on the same side with the lug, and the winding rope is wound on the rotating take-up reel.

Preferably, the first return spring is in a natural state with the telescoping block flush with the helical block.

The invention has the beneficial effects that:

1. the invention adopts the sliding detection probes for detecting the upper surface and the lower surface of the magnesite boards arranged between the adjacent rear support and the front support, and it needs to be noted that the sliding detection probes are connected through a network at the moment, and the sliding detection probes upload the surface condition pictures between the two adjacent magnesite boards to a 5G network in real time in the process of sliding up and down, so that the real-time detection and observation can be conveniently realized, and the timely reaction can be made.

2. The water-absorbing sponge is provided with the water-squeezing plate for squeezing the water-absorbing sponge at the end part, and the water-absorbing sponge can effectively absorb the water on the surface of the magnesite plate, so that the problem of sweating is solved, and the accumulation of the water is avoided.

3. The 'blooming' is generated because the magnesite board reacts with the carbon dioxide in a contact way, and therefore corresponding gas is needed to be isolated, so that oxygen and helium are positioned at the top and the bottom of the magnesite board, and because of the existence of the top fixing plate and the bottom fixing plate, the oxygen and helium can stably exist at the two sides of the top and the bottom of the magnesite board for blocking the carbon dioxide.

Drawings

Fig. 1 is a schematic structural diagram of a magnesite building material production and storage device according to the present invention;

FIG. 2 is a schematic view of the internal structure of a sliding cleaning plate in the storage device for magnesite building materials;

FIG. 3 is a front cross-sectional view of a sliding cleaning plate according to the present invention;

FIG. 4 is a side view of the upper and lower equiangular shafts of the sliding cleaning plate of the present invention;

FIG. 5 is a side view of the left and right equi-angled shafts of the sliding cleaning plate of the present invention;

FIG. 6 is an enlarged view of the structure at A in FIG. 5;

fig. 7 is a schematic structural diagram of a reset driving mechanism in the magnesite building material production and storage device according to the present invention;

fig. 8 is a partially exploded view of the reset driving mechanism according to the present invention.

In the figure: 1 rear support, 2 front support, 3 top fixing plate, 4 sliding cleaning plate, 5 roller groove, 6 magnesite plate, 7 upper gas storage tank, 8 sliding detection probe, 9 driving motor, 10 roller, 11 magnet lug, 12 water absorption sponge, 13 water squeezing plate, 14 air injection pipe, 15 division plate, 16 air inlet pipe, 17 front blocking ring, 18 moving piston, 19 rear blocking ring, 20 elastic pull rope, 21 air outlet pipe, 22 buffer spring, 23 sliding cavity, 24 first hollow pipe, 25 water absorption hole, 26 second hollow pipe, 27 first water inlet valve, 28 water flow pipe, 29 water storage cavity, 30 rotating cover, 31 first sliding groove, 32L-shaped plate, 33 driving shaft, 34 rotating take-up reel, 35 telescopic block, 36 spiral block, 37 spiral groove, 38 fixed block, 39 second sliding groove, 40 lug, 41 rotating curved rod, 42 baffle, 43 winding rope, 44 first reset spring.

Detailed Description

Referring to fig. 1-8, a magnesite building material production strorage device, top fixed plate 3 and bottom fixed plate that set up in magnesite board 6 upper and lower both sides, top fixed plate 3 and bottom fixed plate all fix on vertical rear support 1 and the fore-stock 2 that sets up, refer to fig. 1 and show, such rear support 1 is different with fore-stock 2 structure, the workman of being convenient for gets from getting between two adjacent fore-stocks 2 and put, also can avoid piling up magnesite board 6 simultaneously, cause rigidity destruction to magnesite board 6 below.

Be equipped with the slip test probe 8 that is used for detecting two sides about magnesite board 6 between adjacent after-poppet 1 and fore-stock 2, it needs to explain that, slip test probe 8 at this moment passes through the network connection, and slip test probe 8 is at gliding in-process from top to bottom with the real-time 5G network of uploading of surface condition picture between two adjacent magnesite boards 6, be convenient for can real-time detection observe to timely reaction.

The top of top fixed plate 3 and the bottom of bottom fixed plate all are equipped with gyro wheel groove 5, all are equipped with on top fixed plate 3 and the bottom fixed plate and hug closely 6 gliding slip cleaning plate 4 in surface of magnesite board, can guarantee like this to be hugged closely 6 gliding slip cleaning plate 4 of surface of magnesite board can be through the problem of "frosting" and "sweating" of the timely processing magnesite board 6 surface production of motion.

The sliding cleaning plate 4 rolls in the roller groove 5 through the rollers 10 arranged on two sides, the side wall of the roller 10 is provided with a plurality of magnet lugs 11, the bottom of the roller groove 5 is provided with a magnet groove matched with the magnet lugs 11 on the side wall of the roller 10, so that the sliding cleaning plate 4 on the bottom fixing plate can be stably arranged on the bottom fixing plate through magnetic force, and the phenomenon of skidding caused by the rolling of the roller 10 in the roller groove 5 can be avoided through the buckle between the magnet lugs 11 and the magnet groove.

Referring to fig. 2-5, the roller 10 is rotatably connected to the sliding cleaning plate 4 through a driving shaft 33 penetrating through the sliding cleaning plate 4, the driving shaft 33 is provided with a driving motor 9 for driving, it should be noted that an output end of the driving motor 9 is connected to the driving shaft 33, and the sliding detection probe 8 further issues a corresponding instruction through real-time uploading to the 5G network, that is, when observing that there is a place where the stacked magnesite plates 6 cannot be seen due to an angle problem, so that corresponding phenomena of "frosting" and "sweating" occur, the driving motor 9 drives the driving shaft 33 to rotate, so that the sliding cleaning plate 4 slides against the surface of the magnesite plate 6.

Be equipped with the chamber and the jet-propelled chamber of absorbing water in the clean board 4 that slides, the chamber and the jet-propelled chamber of absorbing water pass through division board 15 to be separated, first sliding tray 31 has been seted up to division board 15 bottom, and it has L shaped plate 32 to slide in first sliding tray 31, it is equipped with the sponge 12 that absorbs water that is used for absorbing moisture to absorb water intracavity, and the sponge 12 tip of absorbing water is equipped with the crowded water board 13 that is used for the extrusion sponge 12 that absorbs water, it needs to explain, the sponge 12 that absorbs water here sets up can effectually take away the moisture on 6 surfaces of magnesite board, thereby the problem of "sweating" has been solved, the piling up of moisture has been avoided.

The water squeezing plate 13 is connected with the L-shaped plate 32, and the L-shaped plate 32 can drive the water squeezing plate 13 to move towards the water absorption sponge 12, so that the effect of squeezing the water absorption sponge 12 is achieved, and water originally absorbed into the water absorption sponge 12 can be squeezed out.

The squeezing plate 13 is connected with the sliding cleaning plate 4 through a water pumping and collecting device, as shown in fig. 5-6, the water pumping and collecting device comprises a plurality of water suction holes 25, a buffer spring 22, a sliding cavity 23, a first hollow tube 24, a second hollow tube 26, a first water inlet valve 27, a second water inlet valve, a water flowing tube 28, a water storage cavity 29 and a rotating cover 30, which are arranged on the squeezing plate 13 and face the water suction sponge 12, the sliding cavity 23 is arranged on the side wall of the water suction cavity, the squeezing plate 13 slides in the sliding cavity 23 through the first hollow tube 24, the plurality of water suction holes 25 are communicated with the first hollow tube 24, the second water inlet valve is arranged in the water suction holes 25, the arrangement can ensure that when the squeezing plate 13 moves towards the water suction sponge 12, water generated by squeezing the water suction sponge 12 can enter the first hollow tube 24 from the water suction holes 25, it is noted that when the squeezing plate 13 moves towards the water suction sponge 12, due to the action of the first water inlet valve 27, the air pressure in the first hollow pipe 24, particularly at the right end of the first water inlet valve 27, is reduced, so that it can be ensured that water generated by the water absorption sponge 12 enters the first hollow pipe 24 due to the action of negative pressure, and the water generated by squeezing the water absorption sponge 12 is prevented from returning to the surface of the magnesite plate 6 again.

One end of the second hollow pipe 26 slides in the first hollow pipe 24 through the first water inlet valve 27, the other end of the second hollow pipe 26 is fixed to one side of the sliding cavity 23, the first water inlet valve 27 and the second water inlet valve are both one-way valves, the water flow of the first water inlet valve 27 faces the first hollow pipe 24, the water flow of the second water inlet valve faces the second hollow pipe 26, and therefore when the wringing plate 13 moves towards the first water inlet valve 27, the pressure in the first hollow pipe 24, particularly the pressure at the right end of the first water inlet valve 27, is increased, water cannot flow out from the second water inlet valve, and the effect of emptying moisture in the first hollow pipe 24 can be achieved when water in the first hollow pipe 24 flows into the second hollow pipe 26 from the first water inlet valve 27.

The second hollow pipe 26 is communicated with the water storage cavity 29 through the water flowing pipe 28, and the bottom of the water storage cavity 29 is provided with a rotary cover 30 for sealing, so that the collected water can be stored in the water storage cavity 29, and then the rotary cover 30 is opened to drain the water from the water storage cavity 29.

The water absorption sponge 12 is tightly attached to the surface of the magnesite plate 6, and the bottom of the rotating cover 30 is higher than the bottom of the water absorption sponge 12, so that the magnesite plate 6 cannot be scratched by the sliding cleaning plate 4 firstly, and is absorbed by the water absorption sponge 12 firstly.

A one-way air injection device is arranged in the air injection cavity and comprises an air injection pipe 14, an air inlet pipe 16, a front stop ring 17, a moving piston 18, a rear stop ring 19, an elastic pull rope 20 and an air outlet pipe 21, wherein the air inlet pipe 16 is connected with a rubber hose, the air inlet pipe 16 is communicated with the air injection pipe 14, the front stop ring 17 and the rear stop ring 19 are respectively positioned at two sides of a communication point of the air inlet pipe 16 and the air injection pipe 14, the moving piston 18 is positioned between the front stop ring 17 and the rear stop ring 19, the moving piston 18 is stretched through the elastic pull rope 20, and one side of the rear stop ring 19, which faces the moving piston 18, is provided with a plurality of second reset springs, so that the air inlet pipe 16 can be blocked when the moving piston 18 moves to be tightly attached to the front stop ring 17; and when the moving piston 18 moves to be clung to the second return spring on the rear stop ring 19 and is positioned for compressing the second return spring, the air inlet pipe 16 is prevented from being blocked, so that the normal circulation of air is facilitated, the air flows to the air injection pipe 14 from the air inlet pipe 16, and is finally sprayed out through the air outlet pipe 21 arranged on the sliding cleaning plate 4, and the air inlet pipe 16 is popped up and blocked by the second return spring when the moving piston 18 is not pulled.

The top of the top fixing plate 3 and the bottom of the bottom fixing plate are respectively provided with an upper gas storage tank 7 and a lower gas storage tank, the upper gas storage tank 7 and the lower gas storage tank are respectively stored with oxygen and helium, the sliding cleaning plate 4 is respectively connected with the upper gas storage tank 7 and the lower gas storage tank through rubber hoses, it is required to explain that the 'blooming' is generated because the magnesite plate 6 is in contact with carbon dioxide to react, corresponding gas is required to be isolated, and then the oxygen and the helium can be positioned at the top and the bottom of the magnesite plate 6, and because the top fixing plate 3 and the bottom fixing plate exist, the oxygen and the helium can stably exist at the top and the bottom of the magnesite plate 6 and are used for separating the carbon dioxide.

Referring to fig. 7-8, a reset driving mechanism is sleeved on the driving shaft 33 and comprises a rotary take-up reel 34, a telescopic block 35, a spiral block 36, a spiral groove 37, a fixing block 38, a second sliding groove 39, a convex block 40, a rotary curved rod 41, a baffle plate 42, a winding rope 43 and a first reset spring 44, wherein the rotary take-up reel 34 rotates on the driving shaft 33 through the telescopic block 35, the telescopic block 35 rotates on the sliding cleaning plate 4 through the first reset spring 44, and the telescopic block 35 is flush with the spiral block 36 when the first reset spring 44 is in a natural state, so that the telescopic block 35 can be driven to rotate together through friction force when the driving shaft 33 rotates, and the rotary telescopic block 35 can drive the rotary take-up reel 34 to rotate together, thereby achieving the effects of winding the winding rope 43 and driving the rotary curved rod 41 to swing.

The rotary take-up reel 34 and the telescopic block 35 slide through a fixed block 38 and a second sliding groove 39 which are circumferentially arranged, the spiral block 36 is circumferentially arranged on the surface of the driving shaft 33, the spiral groove 37 is formed in the inner wall of the telescopic block 35, the spiral groove 37 is matched with the spiral block 36, and it should be noted that when the water squeezing plate 13 and the moving piston 18 are blocked, the rotary take-up reel 34 stops rotating, and when the driving shaft 33 still rotates, the telescopic block 35 is separated from the spiral block 36 and extrudes the first return spring 44.

One end of a rotating curved rod 41 rotates on the rotating take-up reel 34 through a bump 40, the other end of the rotating curved rod 41 is rotatably connected with the L-shaped plate 32 through a pillow block, a baffle 42 is arranged on the rotating take-up reel 34 on the same side with the bump 40, a winding rope 43 is wound on the rotating take-up reel 34, therefore, when the rotating take-up reel 34 rotates forwards or reversely, the L-shaped plate 32 can be driven to do reciprocating motion through the rotating curved rod 41, and an elastic pull rope 20 connected with the winding rope 43 drives a moving piston 18 to do reciprocating motion between a front blocking ring 17 and a rear blocking ring 19, so that the effect that when the sliding cleaning plate 4 moves forwards is achieved, the water absorption sponge 12 is not squeezed by the water squeezing plate 13, the water absorption sponge can absorb water, then the water moves backwards, the effect that the water squeezing can be achieved, the moving piston 18 can be pulled to open an air inlet pipe 16 to jet air, and the surface of the magnesite plate 6 is protected by air jet.

Therefore, the motion of the sliding cleaning plate 4 and the timely cleaning of the surface of the magnesite plate 6 can be realized through the real-time monitoring of 5G, and the corresponding problems of 'frosting' and 'sweating' are prevented.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The magnesite building material production and storage device comprises a top fixing plate (3) and a bottom fixing plate which are arranged on the upper side and the lower side of a magnesite plate (6), wherein the top fixing plate (3) and the bottom fixing plate are fixed on a rear support (1) and a front support (2) which are vertically arranged, and a sliding detection probe (8) for detecting the upper surface and the lower surface of the magnesite plate (6) is arranged between the rear support (1) and the front support (2) and is adjacent to the rear support (3), and is characterized in that roller grooves (5) are formed in the top of the top fixing plate (3) and the bottom of the bottom fixing plate, sliding cleaning plates (4) tightly attached to the surface of the magnesite plate (6) in a sliding manner are arranged on the top fixing plate (3) and the bottom fixing plate, the sliding cleaning plates (4) roll in the roller grooves (5) through rollers (10) arranged on the two sides, and the rollers (10) are rotatably connected with the sliding cleaning plates (4) through driving shafts (33) penetrating through the sliding cleaning plates (4), the cleaning device is characterized in that a driving motor (9) used for driving is arranged on the driving shaft (33), a water absorption cavity and an air injection cavity are arranged in the sliding cleaning plate (4), the water absorption cavity and the air injection cavity are separated through a partition plate (15), a first sliding groove (31) is formed in the bottom of the partition plate (15), an L-shaped plate (32) is arranged in the first sliding groove (31) in a sliding mode, water absorption sponge (12) used for absorbing water is arranged in the water absorption cavity, a water squeezing plate (13) used for squeezing the water absorption sponge (12) is arranged at the end portion of the water absorption sponge (12), the water squeezing plate (13) is connected with the L-shaped plate (32), the water squeezing plate (13) is connected with the sliding cleaning plate (4) through a water pumping and collecting device, a one-way air injection device is arranged in the air injection cavity, an upper air storage tank (7) and a lower air storage tank are respectively arranged at the top of the top fixing plate (3) and the bottom of the bottom fixing plate, go up gas holder (7) and store oxygen and helium respectively in the gas holder down, slip clean board (4) link to each other with last gas holder (7) and lower gas holder respectively through rubber hose, the cover is equipped with reset drive mechanism on drive shaft (33).

2. A magnesite building material production and storage device as claimed in claim 1, wherein the side walls of the roller (10) are provided with a plurality of magnet protrusions (11), and the bottom of the roller groove (5) is provided with a magnet groove adapted to the magnet protrusions (11) on the side walls of the roller (10).

3. The magnesite building material production and storage device as claimed in claim 1, wherein the water pumping and collecting device comprises a plurality of water suction holes (25) formed in the water squeezing plate (13) and facing the water absorbing sponge (12), a buffer spring (22), a sliding cavity (23), a first hollow tube (24), a second hollow tube (26), a first water inlet valve (27), a second water inlet valve, a water flowing tube (28), a water storage cavity (29) and a rotating cover (30), wherein the sliding cavity (23) is formed in a side wall of the water suction cavity, the water squeezing plate (13) slides in the sliding cavity (23) through the first hollow tube (24), the plurality of water suction holes (25) are communicated with the first hollow tube (24), the second water inlet valve is arranged in the water suction holes (25), one end of the second hollow tube (26) slides in the first hollow tube (24) through the first hollow tube (27), the other end of the second hollow pipe (26) is fixed with one side of the sliding cavity (23), the second hollow pipe (26) is communicated with the water storage cavity (29) through a water flowing pipe (28), and the bottom of the water storage cavity (29) is provided with a rotary cover (30) for sealing.

4. A magnesite building material production and storage device as claimed in claim 3, wherein the water absorbing sponge (12) is tightly attached to the surface of the magnesite board (6), and the bottom of the rotary cover (30) is higher than the bottom of the water absorbing sponge (12).

5. A magnesite building material production and storage device as claimed in claim 3, characterised in that the first inlet valve (27) and the second inlet valve are both one-way valves, the first inlet valve (27) is arranged to direct water towards the first hollow tube (24) and the second inlet valve is arranged to direct water towards the second hollow tube (26).

6. A magnesite building material production and storage device as claimed in claim 1, wherein the one-way air injection device comprises an air injection pipe (14), an air inlet pipe (16), a front blocking ring (17), a moving piston (18), a rear blocking ring (19), an elastic pull rope (20) and an air outlet pipe (21), the air inlet pipe (16) is connected with a rubber hose, the air inlet pipe (16) is communicated with the air injection pipe (14), the front blocking ring (17) and the rear blocking ring (19) are respectively located on two sides of a communication point between the air inlet pipe (16) and the air injection pipe (14), the moving piston (18) is located between the front blocking ring (17) and the rear blocking ring (19), the moving piston (18) is stretched through the elastic pull rope (20), and the rear blocking ring (19) is provided with a plurality of second return springs towards one side of the moving piston (18).

7. The magnesite building material production and storage device as claimed in claim 1, wherein the reset driving mechanism comprises a rotary take-up reel (34), a telescopic block (35), a spiral block (36), a spiral groove (37), a fixed block (38), a second sliding groove (39), a projection (40), a rotary curved bar (41), a baffle (42), a winding rope (43) and a first reset spring (44), the rotary take-up reel (34) rotates on the driving shaft (33) through the telescopic block (35), the telescopic block (35) rotates on the sliding cleaning plate (4) through the first reset spring (44), the rotary take-up reel (34) and the telescopic block (35) slide through the fixed block (38) and the second sliding groove (39) which are circumferentially arranged, the spiral block (36) is circumferentially arranged on the surface of the driving shaft (33), the spiral groove (37) is arranged on the inner wall of the telescopic block (35), and spiral groove (37) and spiral piece (36) looks adaptation, rotate curved bar (41) one end and pass through lug (40) and rotate on rotating take-up reel (34), it is connected with L shaped plate (32) rotation to rotate the curved bar (41) other end through the pillow block, baffle (42) are seted up on rotating take-up reel (34) with lug (40) same side, winding rope (43) twines on rotating take-up reel (34).

8. A magnesite building material production and storage device as claimed in claim 7, characterised in that the telescopic block (35) is flush with the spiral block (36) when the first return spring (44) is in its natural state.