CN118003451B - Autoclaved kettle for processing fiber reinforced calcium silicate plates - Google Patents

Abstract

The invention is suitable for the technical field of autoclaves, and provides an autoclaved kettle for processing a fiber reinforced calcium silicate plate, which comprises the following components: the kettle body and the plugging door are arranged on the kettle body; the pressure relief assembly is communicated with the kettle body; the steam pipe is used for inputting steam into the kettle body and is arranged at the inner top of the kettle body; the placing component is used for placing the fiber reinforced calcium silicate board and is arranged in the kettle body in a sliding manner; the invention avoids the problems that high-temperature steam is difficult to fully disperse in the autoclave because the area of the fiber reinforced calcium silicate board is large, the top temperature of the autoclave is obviously higher than the bottom temperature, the steaming effect is poor and the production quality of the fiber reinforced calcium silicate board is seriously affected by the arrangement of the equalizing mechanism.

Description

Autoclaved kettle for processing fiber reinforced calcium silicate plates

Technical Field

The invention relates to the technical field of autoclaves, in particular to an autoclaved for processing a fiber reinforced calcium silicate board.

Background

The main materials of the fiber-reinforced calcium silicate board comprise siliceous materials (such as quartz powder, diatomite and the like), calcareous materials (such as slaked lime) and reinforcing fibers (inorganic mineral fibers or cellulose fibers and the like). After mixing these materials, a preliminary sheet structure is formed by flow forming and slab compaction. In order to improve the strength and stability of the sheet, the sheet to be preliminarily formed needs to be subjected to an autoclaved curing process. In the process, the plate is placed in an autoclave, and is subjected to the action of high-temperature high-pressure saturated steam to accelerate the curing reaction, so that the calcium silicate gel is finally formed. The autoclaved fiber reinforced calcium silicate board has high strength, low heat conductivity coefficient and good fireproof performance, and is an inorganic building board with stable performance.

When the existing autoclave is used, because the area of the fiber reinforced calcium silicate board is large, high-temperature steam is difficult to fully disperse in the autoclave, the condition that the top temperature of the autoclave is obviously higher than the bottom temperature easily exists, the autoclaved effect is poor, and the production quality of the fiber reinforced calcium silicate board is seriously affected. Therefore, in view of the above-mentioned current situation, there is an urgent need to provide an autoclave for processing a fiber-reinforced calcium silicate board, so as to overcome the shortcomings in the current practical application.

Disclosure of Invention

The invention aims to provide an autoclave for processing a fiber-reinforced calcium silicate board, which aims to solve the problems in the background technology.

The invention is realized in such a way that an autoclave for processing fiber reinforced calcium silicate boards comprises:

The kettle body and the plugging door are arranged on the kettle body;

the pressure relief assembly is communicated with the kettle body;

the steam pipe is used for inputting steam into the kettle body and is arranged at the inner top of the kettle body;

The placing component is used for placing the fiber reinforced calcium silicate board and is arranged in the kettle body in a sliding manner;

And the balance mechanism comprises a supporting plate, a movable toothed plate, a turbulent flow mechanism and a control assembly, wherein the supporting plate is fixedly arranged at the inner top of the kettle body, a through hole for a steam pipe to penetrate is formed in the supporting plate, the movable toothed plate is slidably arranged at the bottom of the supporting plate, a driving assembly for driving the movable toothed plate to reciprocate in the supporting plate is further arranged in the kettle body, a shunt pipe for driving the driving assembly to work and guiding steam into the kettle body is arranged on the steam pipe, the turbulent flow mechanism comprises a first turbulent flow assembly and a second turbulent flow assembly, the first turbulent flow assembly is arranged at the bottom of the movable toothed plate, the second turbulent flow assembly is slidably arranged at the bottom of the movable toothed plate through a movable block, the control assembly is connected with the movable block, and the control assembly is slidably matched with the movable toothed plate, and is used for adjusting the working position of the movable block and pushing the movable toothed plate to an initial position.

As a further scheme of the invention: the equalizing mechanisms are arranged in the kettle body at equal intervals, and the structures of the equalizing mechanisms are the same.

As a further scheme of the invention: the shunt tube is of an L-shaped structure.

As a further scheme of the invention: the drive assembly includes:

The first rotating shaft is rotatably arranged in the kettle body, and a first half gear and a first gear are fixedly arranged on the first rotating shaft and are intermittently meshed with the movable toothed plate;

the second rotating shaft is rotatably arranged in the kettle body, a second half gear and a second gear are fixedly arranged on the second rotating shaft, the second gear is meshed with the first gear, when the first half gear is meshed with the movable toothed plate, the second half gear is separated from the movable toothed plate, and when the first half gear is separated from the movable toothed plate, the second half gear is meshed with the movable toothed plate;

and the driving blades are fixedly arranged on the second rotating shaft, a plurality of groups of driving blades are arranged, and the end parts of each group of driving blades are provided with semicircular concave structures.

As a further scheme of the invention: and the second rotating shaft is also fixedly provided with a guide vane, and the guide vane is positioned below the second gear.

As a further scheme of the invention: the first vortex subassembly includes second spoiler, elastic sheet, first spoiler and back shaft, second spoiler and elastic sheet are all installed on the removal pinion rack through the back shaft rotation, and the contained angle between first spoiler and the second spoiler is the acute angle, and the elastic sheet is used for being connected between first spoiler and the second spoiler, and the elastic sheet is V font structure.

As a further scheme of the invention: the second spoiler assembly and the first spoiler assembly are identical in structure, and the first spoiler assembly and the second spoiler assembly are symmetrically arranged at the bottom of the movable toothed plate.

As a further scheme of the invention: the control assembly includes:

The control tube is fixedly arranged on the side wall of the kettle body, is connected with a conduit for conveying gas, and is in sliding connection with the movable toothed plate;

And one end of the supporting rod is fixedly connected with the moving block, the other end of the supporting rod is slidably mounted in the control pipe through the piston, and a tension spring for pulling the piston is further arranged in the control pipe.

As a further scheme of the invention: the pressure relief assembly comprises a pressure relief valve, a conduit and a heat exchanger, one end of the conduit is communicated with the kettle body through the pressure relief valve, and the other end of the conduit is communicated with the heat exchanger.

As a further scheme of the invention: the laying assembly comprises a laying plate and a limiting block, the laying plate is slidably mounted on the inner bottom of the kettle body, a plurality of groups of grooves used for limiting the fiber reinforced calcium silicate plate are formed in the laying plate at equal intervals, and a plurality of groups of limiting blocks are detachably mounted on two sides of each group of grooves.

Compared with the prior art, the invention has the beneficial effects that: the steam pipe is connected with external steam equipment, the fiber reinforced calcium silicate board to be processed is placed in the placement component and pushed into the kettle body, the driving component can be driven to work through the matching arrangement of the steam pipe and the shunt pipe, meanwhile, steam can be input to the periphery of the fiber reinforced calcium silicate board, the driving component can be utilized to drive the movable toothed plate to reciprocate on the supporting plate, extra power is not needed, and accordingly the first turbulence component and the second turbulence component are driven to continuously work in the kettle body, steam can be uniformly spread around the fiber reinforced calcium silicate board, the autoclaved effect is improved, after the processing is finished, the pressure in the kettle body is the same as the external pressure through the pressure relief component, and the processed fiber reinforced calcium silicate board can be pulled out after the plugging door is opened, and the processing is completed; through the setting of balanced mechanism, avoided current cauldron that evaporates when using, because fibre reinforced calcium silicate board area is great for high temperature steam is difficult to fully scatter in evaporating the cauldron, and easily exists the condition that evaporating cauldron top temperature is obviously higher than bottom temperature, and it is relatively poor to evaporate pressure the effect, seriously influences the problem of the production quality of fibre reinforced calcium silicate board.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a schematic cross-sectional view of the present invention.

Fig. 3 is a schematic structural diagram of an equalizing mechanism in the present invention.

Fig. 4 is a schematic top view of fig. 3.

Fig. 5 is a schematic view of the bottom structure of fig. 3.

Fig. 6 is a schematic structural view of a first spoiler assembly according to the present invention.

Fig. 7 is a schematic cross-sectional view of a moving toothed plate and a control tube according to the present invention.

In the accompanying drawings: the device comprises a 1-kettle body, a 2-steam pipe, a 3-relief valve, a 4-guide pipe, a 5-heat exchanger, a 6-plugging door, a 7-placing plate, an 8-limiting block, a 9-supporting plate, a 10-moving toothed plate, an 11-shunt pipe, a 12-first rotating shaft, a 13-first half gear, a 14-first gear, a 15-second rotating shaft, a 16-driving blade, a 17-second half gear, a 18-guiding blade, a 19-second gear, a 20-first spoiler, a 21-second spoiler, a 22-elastic piece, a 23-moving block, a 24-supporting shaft, a 25-controlling pipe, a 26-tension spring, a 27-piston and a 28-supporting rod.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention. Specific implementations of the invention are described in detail below in connection with specific embodiments.

Referring to fig. 1 to 7, an autoclave for processing a fiber-reinforced calcium silicate board according to an embodiment of the present invention includes:

the kettle body 1 and the plugging door 6 arranged on the kettle body 1; wherein the plugging door 6 can be rotatably arranged on the kettle body 1 through a hinge, so that the plugging door is convenient to open and close;

The pressure relief assembly is communicated with the kettle body 1;

a steam pipe 2 for inputting steam into the kettle body 1, wherein the steam pipe 2 is arranged at the inner top of the kettle body 1;

The placing component is used for placing the fiber reinforced calcium silicate board and is arranged in the kettle body 1 in a sliding manner;

And the equalization mechanism comprises a supporting plate 9, a movable toothed plate 10, a turbulent flow mechanism and a control component, wherein the supporting plate 9 is fixedly arranged at the inner top of the kettle body 1, a through hole for a steam pipe 2 to penetrate is formed in the supporting plate 9, the movable toothed plate 10 is slidably arranged at the bottom of the supporting plate 9, a driving component for driving the movable toothed plate 10 to reciprocate on the supporting plate 9 is further arranged in the kettle body 1, the steam pipe 2 is provided with a shunt pipe 11 for driving the driving component to work and for guiding steam into the kettle body 1, the turbulent flow mechanism comprises a first turbulent flow component and a second turbulent flow component, the first turbulent flow component is arranged at the bottom of the movable toothed plate 10, the second turbulent flow component is slidably arranged at the bottom of the movable toothed plate 10 through a movable block 23, the control component is connected with the movable block 23, and is slidably matched with the movable toothed plate 10, and the control component is used for realizing adjustment of the working position of the movable block 23 and pushing the movable toothed plate 10 to the initial position.

In the embodiment of the invention, when the device is used, the steam pipe 2 is connected with external steam equipment, the fiber reinforced calcium silicate board to be processed is placed into the placement component and pushed into the kettle body 1, the driving component can be driven to work through the matching arrangement of the steam pipe 2 and the shunt pipe 11, meanwhile, the driving component can be used for inputting steam into the periphery of the fiber reinforced calcium silicate board, the driving component can be used for driving the movable toothed plate 10 to reciprocate on the supporting plate 9, no extra power is needed, so that the first turbulence component and the second turbulence component are driven to continuously work in the kettle body 1, the steam can be uniformly spread around the fiber reinforced calcium silicate board, the autoclaved effect is improved, after the processing is finished, the pressure in the kettle body 1 is the same as the external pressure through the pressure relief component, the processed fiber reinforced calcium silicate board can be pulled out by opening the sealing door 6, and the processing is finished; compared with the prior art, the invention avoids the problems that the high-temperature steam is difficult to fully disperse in the autoclave because the area of the fiber-reinforced calcium silicate board is large, the top temperature of the autoclave is obviously higher than the bottom temperature, the autoclaved effect is poor and the production quality of the fiber-reinforced calcium silicate board is seriously affected when the traditional autoclave is used by arranging the equalizing mechanism.

In one embodiment of the present invention, referring to fig. 1 to 7, a plurality of groups of equalization mechanisms are equally spaced in the kettle body 1, and the structures of the plurality of groups of equalization mechanisms are the same;

the shunt tube 11 is of an L-shaped structure;

The drive assembly includes:

the first rotating shaft 12 is rotatably arranged in the kettle body 1, a first half gear 13 and a first gear 14 are fixedly arranged on the first rotating shaft 12, and the first half gear 13 is intermittently meshed with the movable toothed plate 10;

the second rotating shaft 15 is rotatably installed in the kettle body 1, and a second half gear 17 and a second gear 19 are fixedly installed on the second rotating shaft 15, wherein the second gear 19 is meshed with the first gear 14, when the first half gear 13 is meshed with the movable toothed plate 10, the second half gear 17 is separated from the movable toothed plate 10, and when the first half gear 13 is separated from the movable toothed plate 10, the second half gear 17 is meshed with the movable toothed plate 10;

The driving blades 16 are fixedly arranged on the second rotating shaft 15, a plurality of groups of driving blades 16 are arranged, and the end part of each group of driving blades 16 is provided with a semicircular concave structure;

a guide vane 18 is fixedly arranged on the second rotating shaft 15, and the guide vane 18 is positioned below the second gear 19; facilitating the downward direction of the steam;

the first spoiler assembly comprises a second spoiler 21, an elastic sheet 22, a first spoiler 20 and a supporting shaft 24, wherein the second spoiler 21 and the elastic sheet 22 are rotatably installed on the movable toothed plate 10 through the supporting shaft 24, an included angle between the first spoiler 20 and the second spoiler 21 is an acute angle, the elastic sheet 22 is used for connecting the first spoiler 20 and the second spoiler 21, and the elastic sheet 22 is of a V-shaped structure;

the second spoiler assembly and the first spoiler assembly have the same structure, and the first spoiler assembly and the second spoiler assembly are symmetrically arranged at the bottom of the movable toothed plate 10;

The control assembly includes:

The control tube 25 is fixedly arranged on the side wall of the kettle body 1, the control tube 25 is connected with a conduit 4 for conveying gas, and the control tube 25 is in sliding connection with the movable toothed plate 10;

the bracing piece 28, the one end and the movable block 23 fixed connection of bracing piece 28, the other end of bracing piece 28 passes through piston 27 slidable mounting in control tube 25, and still is provided with the pulling force spring 26 that is used for carrying out the pulling to piston 27 in the control tube 25.

In this embodiment, in the initial state, the control tube 25 is filled with gas, before the movable rack 10 moves to the side of the control tube 25, the gas in the control tube 25 is discharged by the guide tube 4, the tension spring 26 pulls the piston 27, the support rod 28 and the movable block 23 to the end of the movable rack 10, so that the first turbulence assembly is separated from the second turbulence assembly, when the movable rack 10 moves away from the control tube 25, the gas in the control tube 25 is input into the control tube 25 by the guide tube 4, so that the gas in the control tube 25 pushes the piston 27, the support rod 28 and the movable block 23 to move, so that the second turbulence assembly at the end of the movable rack 10 can move synchronously along with the movable rack 10, through the control of the gas in the control pipe 25, the space is kept between the first turbulence component and the second turbulence component all the time in the moving process of the movable toothed plate 10, after the processing is finished, the gas is introduced into the control pipe 25 by using the guide pipe 4, and the movable toothed plate 10 and the second turbulence component are pushed to reset by using the piston 27, the support rod 28 and the movable block 23; through the matching arrangement of the steam pipe 2 and the shunt pipe 11, high-pressure steam can be sprayed onto the driving blade 16, so that the driving blade 16 drives the second rotating shaft 15 to rotate, meanwhile, the preliminary turbulence effect of the driving blade 16 is utilized, the high-pressure steam sprayed by the shunt pipe 11 can be dispersed into the kettle body 1, the high-pressure steam can be uniformly dispersed around the fiber reinforced calcium silicate board, the second rotating shaft 15 can drive the first gear 14 and the first rotating shaft 12 to rotate in a mode of driving the second gear 19 to rotate, the rotating direction of the first rotating shaft 12 is opposite to the rotating direction of the second rotating shaft 15, the first rotating shaft 12 can drive the first half gear 13 to rotate, the second rotating shaft 15 can drive the second half gear 17 to rotate, through the matching arrangement of the first half gear 13 and the second half gear 17, the movable toothed plate 10 can be mobilized to reciprocate on the supporting plate 9, when the movable toothed plate 10 moves to one side of the second spoiler assembly, under the action of wind resistance, the elastic sheet 22 in the second spoiler assembly is compressed, the included angle between the second spoiler 21 and the first spoiler 20 is reduced, so that steam is pushed to the fiber reinforced calcium silicate plates at two sides conveniently, the included angle between the second spoiler 21 and the first spoiler 20 in the first spoiler assembly is kept unchanged or slightly increased (wherein the movable toothed plate 10 and the movable block 23 can be provided with a stop block for limiting the first spoiler 20 and the second spoiler 21, the included angle between the first spoiler 20 and the second spoiler 21 is always an acute angle), the first spoiler 20 and the second spoiler 21 in the first spoiler assembly are utilized to perform a reverse thrust action on steam, the spoiler effect is further improved, the steam is uniformly dispersed around the fiber reinforced calcium silicate plate, the problem that the temperature difference between the top and the bottom of the kettle body 1 is overlarge is further avoided, when the movable toothed plate 10 moves towards one side of the first spoiler assembly, the included angle between the second spoiler 21 in the first spoiler assembly and the first spoiler 20 is reduced, the included angle between the second spoiler 21 in the second spoiler assembly and the first spoiler 20 is increased, the movable toothed plate 10 drives the spoiler mechanism to reciprocate, the steaming and pressing effect can be further improved.

In one embodiment of the present invention, referring to fig. 1 and 2, the pressure relief assembly includes a pressure relief valve 3, a conduit 4, and a heat exchanger 5, wherein one end of the conduit 4 is communicated with the kettle body 1 through the pressure relief valve 3, and the other end of the conduit 4 is communicated with the heat exchanger 5; wherein the heat exchanger 5 is just by adopting the prior art.

In this embodiment, when the processing is completed and the plugging door 6 needs to be opened, the steam in the kettle body 1 is discharged into the heat exchanger 5 by the pressure release valve 3 and the guide pipe 4, and the heat in the steam can be recycled by the heat exchanger 5, so that energy is saved.

In an embodiment of the present invention, referring to fig. 1 and 2, the placement component includes a placement plate 7 and a limiting block 8, the placement plate 7 is slidably mounted on the inner bottom of the kettle body 1, a plurality of groups of grooves for limiting the fiber reinforced calcium silicate plate are formed on the placement plate 7 at equal intervals, and a plurality of groups of limiting blocks 8 are detachably mounted on two sides of each group of grooves.

In the embodiment, each group of grooves is positioned between two adjacent groups of equalization mechanisms, when the device is used, a fiber reinforced calcium silicate board can be placed in the grooves, then the clamping and fixing of the fiber reinforced calcium silicate board are realized by using the limiting block 8, and the placing plate 7 is convenient for feeding the fiber reinforced calcium silicate board into the kettle body 1 or pulling out the processed fiber reinforced calcium silicate board in a manner of being slidably arranged in the kettle body 1; the limiting block 8 is detachably connected with the placing plate 7 through screws, the limiting block 8 can be of a triangular structure, and after the movable toothed plate 10 and the second turbulence assembly are reset, the entering and exiting of the fiber reinforced calcium silicate plate cannot be affected.

In the present invention, unless explicitly specified and limited otherwise, the terms "slide", "rotate", "fixed", "provided" and the like are to be construed broadly, and may be, for example, welded, bolted, or integrated; can be mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (9)

1. The utility model provides a fiber reinforced calcium silicate board processing is with evaporating kettle, includes the cauldron body and sets up the shutoff door on the cauldron body, its characterized in that still includes:

the pressure relief assembly is communicated with the kettle body;

the steam pipe is used for inputting steam into the kettle body and is arranged at the inner top of the kettle body;

The placing component is used for placing the fiber reinforced calcium silicate board and is arranged in the kettle body in a sliding manner;

The balance mechanism comprises a support plate, a movable toothed plate, a turbulent flow mechanism and a control assembly, wherein the support plate is fixedly arranged at the inner top of the kettle body, a through hole for a steam pipe to penetrate is formed in the support plate, the movable toothed plate is slidably arranged at the bottom of the support plate, a driving assembly for driving the movable toothed plate to reciprocate in the support plate is further arranged in the kettle body, a shunt pipe for driving the driving assembly to work and for guiding steam into the kettle body is arranged on the steam pipe, the turbulent flow mechanism comprises a first turbulent flow assembly and a second turbulent flow assembly, the first turbulent flow assembly is arranged at the bottom of the movable toothed plate, the second turbulent flow assembly is slidably arranged at the bottom of the movable toothed plate through a movable block, the control assembly is connected with the movable block, and the control assembly is slidably matched with the movable toothed plate, and is used for adjusting the working position of the movable block and pushing the movable toothed plate to an initial position;

The drive assembly includes:

The first rotating shaft is rotatably arranged in the kettle body, and a first half gear and a first gear are fixedly arranged on the first rotating shaft and are intermittently meshed with the movable toothed plate;

the second rotating shaft is rotatably arranged in the kettle body, a second half gear and a second gear are fixedly arranged on the second rotating shaft, the second gear is meshed with the first gear, when the first half gear is meshed with the movable toothed plate, the second half gear is separated from the movable toothed plate, and when the first half gear is separated from the movable toothed plate, the second half gear is meshed with the movable toothed plate;

and the driving blades are fixedly arranged on the second rotating shaft, a plurality of groups of driving blades are arranged, and the end parts of each group of driving blades are provided with semicircular concave structures.

2. The autoclave for processing a fiber-reinforced calcium silicate board according to claim 1, wherein a plurality of groups of equalization mechanisms are arranged in the autoclave body at equal intervals, and the plurality of groups of equalization mechanisms have the same structure.

3. The autoclave for processing a fiber-reinforced calcium silicate board according to claim 1, wherein the shunt tube has an L-shaped structure.

4. The autoclave for processing a fiber-reinforced calcium silicate board according to claim 1, wherein a guide vane is fixedly installed on the second rotating shaft, and the guide vane is located below the second gear.

5. The autoclave for processing a fiber-reinforced calcium silicate board according to claim 1, wherein the first turbulence assembly comprises a second turbulence plate, an elastic sheet, a first turbulence plate and a supporting shaft, the second turbulence plate and the elastic sheet are both rotatably mounted on the movable toothed plate through the supporting shaft, an included angle between the first turbulence plate and the second turbulence plate is an acute angle, the elastic sheet is used for connection between the first turbulence plate and the second turbulence plate, and the elastic sheet is of a V-shaped structure.

6. The autoclave for processing a fiber-reinforced calcium silicate board according to claim 5, wherein the second turbulence assembly and the first turbulence assembly have the same structure, and the first turbulence assembly and the second turbulence assembly are symmetrically arranged at the bottom of the movable toothed plate.

7. The autoclave for processing a fiber reinforced calcium silicate board according to claim 1, wherein the control assembly comprises:

The control tube is fixedly arranged on the side wall of the kettle body, is connected with a conduit for conveying gas, and is in sliding connection with the movable toothed plate;

And one end of the supporting rod is fixedly connected with the moving block, the other end of the supporting rod is slidably mounted in the control pipe through the piston, and a tension spring for pulling the piston is further arranged in the control pipe.

8. The autoclave for processing a fiber-reinforced calcium silicate board according to claim 1, wherein the pressure release assembly comprises a pressure release valve, a conduit and a heat exchanger, one end of the conduit is communicated with the autoclave body through the pressure release valve, and the other end of the conduit is communicated with the heat exchanger.

9. The autoclave for processing the fiber-reinforced calcium silicate board according to claim 1, wherein the placement component comprises a placement plate and a limiting block, the placement plate is slidably mounted on the inner bottom of the autoclave body, a plurality of groups of grooves for limiting the fiber-reinforced calcium silicate board are formed in the placement plate at equal intervals, and a plurality of groups of limiting blocks are detachably mounted on two sides of each group of grooves.