CN117722837B - Drying device is used in insulation material production - Google Patents

Abstract

The invention discloses a drying device for heat preservation material production, which relates to the technical field of heat preservation material drying and comprises a drying bin, wherein a material changing mechanism is arranged on the inner wall of the drying bin, and a recycling mechanism is fixedly connected to the side wall of the drying bin. According to the invention, in the process that the heat-insulating material rotates in the shell, microwaves are utilized to rapidly heat the heat-insulating material, the microwaves penetrate into the heat-insulating material, so that moisture in the heat-insulating material is rapidly heated and evaporated, the evaporated moisture is driven by the airflow, the moisture in the airflow is collected, the water is conveniently recycled, the dehydrated airflow is used for secondary drying of the heat-insulating material, the drying efficiency is improved, and the air above the air inlet pipe is heated after the airflow is discharged out of the shell, so that the subsequent airflow can be heated more rapidly after entering the shell, and the drying efficiency is improved again to a certain extent.

Description

Drying device is used in insulation material production

Technical Field

The invention relates to the technical field of heat preservation material drying, in particular to a drying device for heat preservation material production.

Background

In the production process of the heat insulation material, the quality of the heat insulation material can be influenced by moisture in the material, such as deterioration, mildew and other problems caused by excessive moisture in foods, the quality of the product can be reduced by the material with excessive humidity in the industrial field, the growth of bacteria, mold and the like can be easily caused by the moisture in the material, the storage life of the material can be prolonged by removing the moisture, and adverse phenomena such as uneven drying color, product adhesion and the like can be caused in the production process of the material with excessive humidity, so that the production efficiency is seriously influenced. The problems can be solved by drying the materials, and the production efficiency is improved.

The existing drying device heats the heat-insulating material through the heating wire and the fan in the using process, so that the heat-insulating material is dried, but the heat-insulating material is heated unevenly in the drying process, and the heat-insulating material is dried unevenly easily.

The prior patent (publication number: CN 208567402U) discloses a drying device for heat insulation materials, which comprises a barrel body, a driving motor, a rectifying board, a filter plate and a blast pipe; the driving motor is arranged right above the barrel body, the rectifying plate is transversely arranged in the barrel body, the filter plate is transversely arranged in the barrel body below the rectifying plate, and the blast pipe is arranged at one side outside the barrel body; the blast pipe is provided with the air blower, so that the drying efficiency of the blast pipe through the drying device is high, the drying effect is good, and uneven drying caused by the fact that the heat-insulating materials are piled and agglomerated after being fed is avoided; the device has the advantages of convenience in unloading, simple structure, uniform rising of the drying gas and uniform area of the heat insulation material subjected to the drying gas.

However, the above technical scheme still has certain defects, in the use process, the above patent still uses the traditional hot air blowing mode to dry, and the heat of the air flow is not easy to permeate into the heat insulation material in the drying process, so that the long time is required in the drying process to finish the drying, the drying efficiency is low, and therefore, the drying device for the production of the heat insulation material is provided.

Disclosure of Invention

Based on the above, the present invention aims to provide a drying device for producing heat insulation materials, so as to solve the technical problems that a long time is required to finish the drying process and the drying efficiency is low in the drying process proposed in the background.

In order to achieve the above purpose, the present invention provides the following technical solutions: the drying device for producing the heat insulation material comprises a drying bin, wherein a material changing mechanism is arranged on the inner wall of the drying bin, and a recycling mechanism is fixedly connected to the side wall of the drying bin;

The drying bin comprises a shell, wherein the inner wall of the shell is rotationally connected with a main synchronous wheel, two ends of the main synchronous wheel extend out of two sides of the shell respectively, the inner wall of the shell is rotationally connected with a plurality of groups of auxiliary synchronous wheels, a plurality of groups of auxiliary synchronous wheels and the main synchronous wheel are rectangular and distributed in the shell, the outer walls of the main synchronous wheel and the plurality of groups of auxiliary synchronous wheels are sleeved with two groups of synchronous belts, the side wall of the shell is fixedly connected with a driving motor, the output end of the driving motor is fixedly connected to one end of the main synchronous wheel, the bottom end of the inner wall of the shell is fixedly connected with two groups of microwave emitting devices, the bottom end of the shell is fixedly connected with two groups of guided wave pipes, the top ends of the two groups of microwave emitting devices extend into the interior of one group of guided wave pipes respectively, the bottom end of the shell is fixedly connected with an auxiliary motor positioned between the two groups of guided wave pipes, the output end of the auxiliary motor is fixedly connected with a reflecting impeller, the side wall of the shell is fixedly connected with an air inlet pipe, the inner wall of the air inlet pipe is fixedly connected with a motor near the top end position of the motor, the output end of the air inlet motor is fixedly connected with a fan positioned in the interior of the air inlet pipe, the bottom end of the air inlet is fixedly connected with the air inlet window, and the top ends of the air inlet window are respectively communicated with the air inlet and are communicated with the top side of the shell, and the air inlet window is communicated with the air inlet and the air inlet is arranged at the top side of the air inlet and the air inlet;

The recovery mechanism comprises a rotary table, the other end at main synchronizing wheel is connected with to the lateral wall rotation of rotary table, the lateral wall fixedly connected with connecting rod of shell is the storehouse body down, the top intercommunication of the storehouse body has the storehouse body down, the lateral wall intercommunication of the storehouse body has the one end of pipeline down, the other end intercommunication of pipeline is in the inside of interior storehouse, the top intercommunication of the storehouse body has the rubber sleeve, the top fixedly connected with clamp plate of rubber sleeve, the top fixedly connected with of clamp plate is in the bottom of connecting rod, the storehouse body is provided with first check valve in the department with pipeline intercommunication, the storehouse body is provided with the second check valve in the department with the storehouse body intercommunication down, the inner wall fixedly connected with of the storehouse body is two sets of filter cottons down, the inner wall fixedly connected with of the storehouse body is located the active carbon of filter cottons below down, the bottom intercommunication of the storehouse body has the drain pipe down, the bottom fixedly connected with of shell is located the collecting box of drain pipe below.

As an optimal technical scheme of the drying device for heat insulation material production, the inner wall of the air inlet is provided with an inclined angle, the inner wall of the shell is provided with an inner bin, the side wall of the inner bin is provided with a plurality of groups of openings, the positions of the plurality of groups of openings respectively correspond to one group of air inlets, the inner wall of the inner bin is fixedly connected with a plurality of groups of heat-conducting plates, the side walls of the plurality of groups of heat-conducting plates are respectively fixedly connected with one group of elastic sheets, the tail ends of the elastic sheets are fixedly connected with metal sheets, and the top end of the inner bin is provided with two groups of hot air inlets.

As an optimal technical scheme of the drying device for producing the heat insulation material, the material changing mechanism comprises a bracket, two groups of brackets are connected to the side wall of the shell in a sliding manner, a plurality of groups of fixing arms are fixedly connected to the side wall of the two groups of synchronous belts, a grid frame is arranged between the two groups of fixing arms positioned at the same horizontal height, two groups of rectangular columns are fixedly connected to the side wall of the grid frame, and the two groups of rectangular columns are respectively connected to the inside of one group of fixing arms in a sliding manner.

As a preferred technical scheme of the drying device for producing the heat insulation material, the bracket comprises the sliding block, the sliding block is slidably connected to the side wall of the shell, the top end of the sliding block is fixedly connected with the cover plate, the side wall of the sliding block is fixedly connected with the support extending to the inside of the shell, two groups of grooves are formed in the top end of the support, two groups of inclined blocks are fixedly connected to the outer wall of the support beside the two groups of grooves respectively, and one group of sliding grooves are formed in the bottom ends of the plurality of groups of inclined blocks respectively.

As a preferable technical scheme of the drying device for producing the heat insulation material, the fixing arm comprises a support arm, one end of the support arm is fixedly connected to the side wall of the synchronous belt, the other end of the support arm is fixedly connected with a fixing block, the inner walls of the fixing block are slidably connected with a plurality of groups of limiting blocks extending to the outside of the fixing block, the inner walls of the two groups of limiting blocks positioned above are slidably connected with a group of sliding plates extending to the outside of the limiting blocks respectively, the thickness of the sliding plates is matched with that of a chute, and the top ends of the fixing blocks are fixedly connected with two groups of guide plates.

As a preferable technical scheme of the drying device for producing the heat insulation material, one end of the limiting block, which is positioned in the fixed block, is fixedly connected with a first reset spring, the tail end of the first reset spring is fixedly connected with the inner wall of the fixed block, one end of the sliding plate, which is positioned in the limiting block, is fixedly connected with a second reset spring, and the tail end of the second reset spring is fixedly connected with the inner wall of the limiting block.

In summary, the invention has the following advantages:

1. according to the invention, in the process that the heat-insulating material rotates in the shell, microwaves are utilized to rapidly heat the heat-insulating material, the microwaves penetrate into the heat-insulating material, so that moisture in the heat-insulating material is rapidly heated and evaporated, the evaporated moisture is driven by airflow and the moisture in the airflow is collected, the water is convenient to recycle subsequently, the dehydrated airflow is used for drying the heat-insulating material for the second time, the drying efficiency is improved, and the air above the air inlet pipe is heated after the airflow is discharged out of the shell, so that the subsequent airflow can be heated more rapidly after entering the shell, and the drying efficiency is improved to a certain extent;

2. According to the invention, the heat insulation material is placed in the grid frame, the rectangular column is contacted in the ascending process of the fixed block, and the rectangular column is fixed in the fixed block, so that the grid frame can move in the shell under the drive of the synchronous belt, and the rectangular column is loosened in the downward movement process of the fixed block, so that the rectangular column is placed on the support, and the grid frame can be conveniently taken out from the shell, and the heat insulation material can be more conveniently fed and discharged in the drying process;

3. According to the invention, the turntable is driven to rotate in the process of rotating the main synchronous wheel, so that the pressing plate repeatedly compresses and stretches the rubber sleeve, when the rubber sleeve is pulled up, water at the bottom end of the inner wall of the inner bin is sucked into the upper bin body through the pipeline, when the rubber sleeve is compressed, the water in the upper bin body is pressed into the lower bin body, and after being filtered by the filter cotton and the activated carbon, the water flows into the collecting box through the drainage pipe, so that the water is reused in the processing process of the heat insulation material, the waste of water resources is reduced, and the water consumption cost in the production process of the heat insulation material is reduced.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic cross-sectional view of an air inlet pipe according to the present invention;

FIG. 3 is a schematic cross-sectional view of the housing of the present invention;

FIG. 4 is a schematic view of the internal structure of the housing of the present invention;

FIG. 5 is an enlarged schematic view of the structure shown at A in FIG. 4;

FIG. 6 is a schematic view of the back structure of the housing of the present invention;

FIG. 7 is a schematic view of the cross-sectional structure of the lower bin of the invention;

FIG. 8 is a schematic view showing the relationship between the fixing block and the bracket during the downward movement of the fixing block;

FIG. 9 is a schematic view showing the bottom view of the fixing block of the present invention during the downward movement;

FIG. 10 is a schematic cross-sectional view of a stopper according to the present invention;

FIG. 11 is a schematic side view of the bracket of the present invention;

fig. 12 is a schematic top view of the bracket of the present invention.

In the figure: 1. a drying bin; 2. a material changing mechanism; 3. a recovery mechanism;

101. a housing; 102. a master synchronizing wheel; 103. a driving motor; 104. an auxiliary synchronizing wheel; 105. a synchronous belt; 106. a microwave emitting device; 107. a waveguide; 108. an auxiliary motor; 109. a reflection impeller; 110. an air inlet pipe; 111. an induced draft motor; 112. a fan; 113. an air inlet; 114. an inner bin; 115. an opening; 116. a heat conductive plate; 117. an elastic sheet; 118. a metal sheet; 119. a grid frame; 1191. rectangular columns; 120. an air outlet; 121. a hot air port;

201. A bracket; 2011. a slide block; 2012. a cover plate; 2013. a bracket; 2014. a groove; 2015. a sloping block; 2016. a chute; 202. a fixed arm; 2021. a support arm; 2022. a fixed block; 2023. a limiting block; 2024. a sliding plate; 2025. a first return spring; 2026. a second return spring; 2027. a guide plate;

301. A turntable; 302. a connecting rod; 303. a lower bin body; 304. a loading bin body; 305. a pipe; 306. a rubber sleeve; 307. a pressing plate; 308. a drain pipe; 309. a collection box; 310. filtering cotton; 311. activated carbon; 312. a first one-way valve; 313. and a second one-way valve.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the invention.

Hereinafter, an embodiment of the present invention will be described in accordance with its entire structure.

The drying device for producing the heat insulation material comprises a drying bin 1, wherein a material changing mechanism 2 is arranged on the inner wall of the drying bin 1, and a recovery mechanism 3 is fixedly connected to the side wall of the drying bin 1;

The drying bin 1 comprises a shell 101, a main synchronous wheel 102 is rotatably connected to the inner wall of the shell 101, two ends of the main synchronous wheel 102 extend out of two sides of the shell 101 respectively, a plurality of groups of auxiliary synchronous wheels 104 are rotatably connected to the inner wall of the shell 101, the auxiliary synchronous wheels 104 and the main synchronous wheel 102 are distributed in the shell 101 in a rectangular mode, two groups of synchronous belts 105 are sleeved on the outer walls of the main synchronous wheel 102 and the auxiliary synchronous wheels 104, a driving motor 103 is fixedly connected to the side wall of the shell 101, the output end of the driving motor 103 is fixedly connected to one end of the main synchronous wheel 102, two groups of microwave emitting devices 106 are fixedly connected to the bottom end of the inner wall of the shell 101, two groups of guided wave tubes 107 are fixedly connected to the bottom end of the shell 101, the top ends of the two groups of the microwave emitting devices 106 extend into the guided wave tubes 107 respectively, an auxiliary motor 108 positioned between the two groups of guided wave tubes 107 is fixedly connected to the bottom end of the shell 101, the output end of the auxiliary motor 108 is fixedly connected with a reflection impeller 109, the side wall of the shell 101 is fixedly connected with an air inlet pipe 110, the inner wall of the air inlet pipe 110 is fixedly connected with an air suction motor 111 near the top end, the output end of the air suction motor 111 is fixedly connected with a fan 112 positioned in the air inlet pipe 110, the bottom ends of the air inlet pipes 110 are respectively communicated with two sides of the shell 101, the shell 101 is provided with an air inlet 113 at the position communicated with the air inlet 110, the top end of the shell 101 is communicated with an air outlet 120, the side wall of the shell 101 is provided with an observation window, glass is fixed on the observation window, the inner wall of the air inlet 113 is provided with an inclined angle, the inner wall of the shell 101 is provided with an inner bin 114, the side wall of the inner bin 114 is provided with a plurality of groups of openings 115, the positions of the groups of openings 115 respectively correspond to one group of air inlets 113, the inner wall of the inner bin 114 is fixedly connected with a plurality of groups of heat conducting plates 116, the side walls of the groups of heat conducting plates 116 are respectively fixedly connected with one group of elastic pieces 117, the end fixedly connected with sheetmetal 118 of elastic piece 117, two sets of hot air ports 121 have been seted up on the top of interior storehouse 114, feed mechanism 2 includes bracket 201, the lateral wall sliding connection of shell 101 has two sets of brackets 201, the lateral wall fixedly connected with multiunit fixed arm 202 of two sets of hold-in range 105, be provided with grid frame 119 between two sets of fixed arms 202 that are located same level, the lateral wall fixedly connected with two sets of rectangular columns 1191 of grid frame 119, two sets of rectangular columns 1191 are sliding connection in the inside of a set of fixed arm 202 respectively.

The main synchronous wheel 102 is driven to rotate by the driving motor 103, so that the main synchronous wheel 102 drives the two groups of synchronous belts 105 to rotate simultaneously, the fixed arm 202 is driven to rotate in the process of rotating the synchronous belts 105, the rectangular column 1191 on the fixed arm 202 drives the grid frame 119 to rotate, the rotating speed of the driving motor 103 is set to be a slower rotating speed, meanwhile, the air suction motor 111 drives the fan 112 to rotate, the fan 112 blows air into the air inlet pipe 110, the air is blown into the shell 101 through the plurality of groups of air inlets 113, the rectangular column 1191 is slidably connected in the fixed arm 202 and cannot rotate, the grid frame 119 on the left side in the fourth is in an upward movement, the grid frame 119 on the right side is in a downward movement, the grid frame 119 is in an inclined state in the ascending and descending processes, after the air enters the shell 101 through the air inlets 113, when the grid frame 119 passes through the air inlet 113, the air flow can be fully blown into the grid frame 119, the microwave emitting device 106 in the shell 101 emits microwaves, the microwave emitting device 106 is a common device in the prior microwave oven and other equipment, the microwaves are guided by the wave guide pipe 107 to contact the reflecting impeller 109, the outer wall of the reflecting impeller 109 is an arc surface, the auxiliary motor 108 drives the reflecting impeller 109 to rotate continuously, so that the microwaves can be uniformly reflected into the shell 101 after contacting the reflecting impeller 109, all the heat insulation materials can uniformly receive the microwaves, the microwaves fully heat the moisture in the heat insulation materials, the moisture is evaporated, the air flow takes away the moisture evaporated by the heat insulation materials in the grid frame 119 in the process of passing through the grid frame 119, the temperature of the air flow is increased and the humidity is increased, these air flows enter the interior of the inner bin 114 through the corresponding openings 115 after passing through the grid frame 119, at this time, the high-temperature humid air flows contact the heat conducting plate 116 and the metal sheet 118, so that moisture in the air flows is condensed into water drops on the surfaces of the metal sheet 118 and the heat conducting plate 116, the surface of the heat conducting plate 116 absorbs heat in the process of continuously condensing the water drops, then the heat is transferred to the side wall of the inner bin 114, the heat is transferred to the shell through the side wall of the inner bin 114 and finally diffused into the air, and under the blowing of the air flows, the metal sheet 118 drives the elastic sheet 117 to bend, and is reset under the action of resilience force of the elastic sheet 117, so that the metal sheet 118 continuously shakes, contact is generated between the metal sheets 118 in the process of shaking the metal sheet 118, and contact is generated between the metal sheet 118 and the heat conducting plate 116, so that the water drops on the surfaces of the metal sheet 118 and the heat conducting plate 116 can fall to the bottom end of the inner bin 114 from the outer walls of the metal sheet 118 and the heat conducting plate 116 more quickly, the air flow is dried after passing through the rear edges of the metal sheet 118 and the heat conducting plate 116, and then discharged from the heat sealing port at the top end of the inner bin 114, so that the grid frame 119 passing through the top end of the inner bin 114 is heated again, the heat insulation material inside the grid frame 119 is further dried, and then the high-temperature air is discharged through the air outlet 120, as can be seen in the second and third figures, the hot air is discharged right above the air suction motor 111 after the hot air is discharged through the air outlet 120, so that the temperature of the air above the air inlet pipe 110 is increased, the air sucked into the air inlet pipe 110 is higher, and then the air discharged into the casing 101 is heated more quickly, so that a virtuous cycle is generated, and the air entering the casing 101 from the air inlet 113 is heated more quickly.

Referring to fig. 1, fig. 4, fig. 8, fig. 9 and fig. 10, the bracket 201 includes a slider 2011, the slider 2011 is slidably connected to a side wall of the housing 101, a cover 2012 is fixedly connected to a top end of the slider 2011, a bracket 2013 extending to an inside of the housing 101 is fixedly connected to a side wall of the slider 2011, two sets of grooves 2014 are provided at a top end of the bracket 2013, two sets of inclined blocks 2015 are fixedly connected to an outer wall of the bracket 2013 beside the two sets of grooves 2014, a set of sliding grooves 2016 are provided at a bottom end of the plurality of sets of inclined blocks 2015, the fixing arm 202 includes a support arm 2021, one end of the support arm 2021 is fixedly connected to a side wall of the synchronous belt 105, the other end of the support arm 2021 is fixedly connected to a fixing block 2022, a plurality of sets of limiting blocks 2023 extending to an outside of the fixing block 2022 are slidably connected to an inner wall of the fixing block 2022, a set of sliding plates 2024 extending to an outside of the limiting blocks 2023 are slidably connected to an inner wall of the lower portion of the fixing block 2023, a thickness of the sliding plates 2024 is matched with the sliding grooves, the top end of the fixing block 2022 is fixedly connected to two sets of guiding plates 2027, a bottom end of the fixing block 2023 is fixedly connected to a first end of the limiting block 2023 is fixedly connected to a second end of the first end of the reset spring 2025, and a reset spring 2025 is fixedly connected to a second end of the first end of the reset spring 2025 is fixedly connected to a first end of the reset spring 2026.

In the process of feeding and discharging, two staff are required to operate the two groups of material changing mechanisms 2 respectively, when the sliding block 2011 on the left side in the four figures is pulled out of the shell 101, the sliding block 2011 drives the cover plate 2012 and the bracket 2013 to slide out of the shell 101, at the moment, the grid frame 119 filled with environment-friendly materials is placed above the two groups of brackets 2013, so that the two groups of rectangular columns 1191 on the side wall of the grid frame 119 slide into the two groups of grooves 2014 on the top end of the bracket 2013, then the positions of the groups of fixing arms 202 are observed through the observation window, then the sliding block 2011 is pushed, so that the sliding block 2011 pushes the bracket 2013 to slide into the shell 101, then the supporting arm 2021 is driven in the process of rotating the synchronous belt 105, so that the supporting arm 2021 drives the fixing block 2022 to rotate, the fixing block 2022 moves to the lower part of the rectangular columns 1191 in the process of rotating, so that the rectangular columns 1191 are positioned between the two groups of guide plates 2027, and along with the movement of the fixing block 2022, pushing the rectangular column 1191 to slide out from the inside of the recess 2014, in the process, the rectangular column 1191 contacts with the two upper groups of limiting blocks 2023 again, under the action of the self weight of the grid frame 119 and the rectangular column 1191, the two groups of limiting blocks 2023 are pushed to slide inside the fixed block 2022, when the rectangular column 1191 slides between the groups of limiting blocks 2023, the first return spring 2025 pushes the limiting blocks 2023 to reset, so that the rectangular column 1191 is blocked by the groups of limiting blocks 2023, in the process, the sliding plate 2024 on the lower two groups of limiting blocks 2023 slides inside the sliding groove 2016, and as the fixed block 2022 rises, the sliding block is pushed by the sliding groove 2016 to move inside the fixed block 2022, and compresses the second return spring 2026, so that the two lower groups of fixed blocks 2022 do not compress the first return spring 2025 in the process of rising of the fixed block 2022, then the grid frame 119 rotates inside the housing 101 under the drive of the fixed block 2022, then, when the worker pulls the left sliding block 2011 to drive the left bracket 2013 to slide out of the housing 101, and repeats the above operation again, the synchronous belt 105 drives the support arm 2021 to move downwards, the support arm 2021 drives the fixed block 2022 to move downwards, so that the fixed block 2022 approaches the bracket 2013 at the other side, as the fixed block 2022 continues to move downwards, so that two groups of limiting blocks 2023 far away from one end of the guide plate 2027 approach the inclined block 2015, so that the side walls of the two groups of sliding plates 2024 are abutted against the inclined surface of the inclined block 2015, at this time, the rectangular column 1191 is driven by the fixed block 2022 to slide into the groove 2014, as the fixed block 2022 continues to move downwards, the two groups of sliding plates 2024 move to two sides under the pushing of the inclined block 2012, so as to move the two groups of limiting blocks 2023 to slide to two sides, and compress the first reset spring 2025, so that the two groups of limiting blocks 1193 are not on the blocking rectangular column 2011, then the two groups of rectangular column 1191 are supported by the bracket 2013, as the fixed block 2022 continues to move downwards, so that the rectangular column 1191 is continuously separated from the bracket 2013, and then the right sliding block 2013 is pulled out of the rectangular column 2013, and the position of the grid frame is continuously, and the grid frame is pulled out of the grid frame 119 by the right sliding block 2013, and then the grid frame is pulled out by the operation, and the grid frame 119 is confirmed, and the position is pulled by the lower frame 2013, and then the lower position is pulled by the lower frame and is separated from the lower frame and then the position of the grid frame is taken.

Referring to fig. 4 to 7, the recovery mechanism 3 includes a turntable 301, the turntable 301 is fixedly connected to the other end of the main synchronizing wheel 102, a connecting rod 302 is rotatably connected to a side wall of the turntable 301, a lower bin body 303 is fixedly connected to a side wall of the casing 101, an upper bin body 304 is connected to a top end of the lower bin body 303, a side wall of the upper bin body 304 is connected to one end of a pipe 305, the other end of the pipe 305 is connected to the inside of the inner bin 114, a rubber sleeve 306 is connected to a top end of the upper bin body 304, a pressing plate 307 is fixedly connected to a top end of the pressing plate 307 at a bottom end of the connecting rod 302, a first check valve 312 is disposed at a position where the upper bin body 304 is connected to the pipe 305, a second check valve 313 is disposed at a position where the upper bin body 304 is connected to the lower bin body 303, two groups of filter cotton 310 are fixedly connected to an inner wall of the lower bin body 303, an activated carbon 311 is fixedly connected to an inner wall of the lower bin body 303 below the filter cotton 310, a bottom end of the lower bin body is connected to a drain 308, and a collection box 309 is fixedly connected to a bottom end of the casing 101 below the drain 308.

By driving the turntable 301 to rotate during the rotation of the main synchronizing wheel 102, the turntable 301 drives the pressing plate 307 to reciprocate up and down through the connecting rod 302 during the rotation, so that the pressing plate 307 repeatedly compresses and stretches the rubber sleeve 306, when the rubber sleeve 306 is pulled up, negative pressure is generated inside the rubber sleeve 306, so that the first one-way valve 312 is adsorbed to be opened, the second one-way valve 313 is tightly closed under the adsorption effect of the negative pressure, so that water at the bottom end of the inner wall of the inner bin 114 is sucked into the upper bin body 304 through the pipeline 305, when the rubber sleeve 306 is compressed, the pressure inside the upper bin body 304 is increased, so that the first one-way valve 312 is tightly closed, the second one-way valve 313 is pushed to be opened, so that water inside the upper bin body 304 is pressed into the lower bin body 303, and after the water is filtered by the filter cotton 310 and the activated carbon 311, the water flows into the collecting bin 309 through the drain pipe 308, so that the water is reused in the processing of the heat insulation material.

During the use, through the in-process that keeps warm the material at the inside pivoted of shell 101, utilize the microwave to carry out rapid heating to the heat preservation material, thereby make the inside moisture of heat preservation material evaporate fast, and utilize the air current to drive the steam of evaporation, and collect the moisture in the air current, be convenient for follow-up carry out recycle to these waters, the air current after the dehydration carries out the secondary drying to the heat preservation material, improve the efficiency of stoving, and heat the air of intake pipe top after the air current discharge shell 101, be convenient for follow-up air current can be faster after entering into shell 101 inside intensification, thereby improved drying efficiency again to a certain extent, the device does not involve the part and all is the same with prior art or can adopt prior art to realize.

Although embodiments of the invention have been shown and described, the detailed description is to be construed as exemplary only and is not limiting of the invention as the particular features, structures, materials, or characteristics may be combined in any suitable manner in any one or more embodiments or examples, and modifications, substitutions, variations, etc. may be made in the embodiments as desired by those skilled in the art without departing from the principles and spirit of the invention, provided that such modifications are within the scope of the appended claims.

Claims (6)

1. Drying device is used in insulation material production, including stoving storehouse (1), its characterized in that: the inner wall of the drying bin (1) is provided with a material changing mechanism (2), and the side wall of the drying bin (1) is fixedly connected with a recycling mechanism (3);

The drying bin (1) comprises a shell (101), a main synchronous wheel (102) is rotationally connected to the inner wall of the shell (101), two sides of the shell (101) are respectively extended from two ends of the main synchronous wheel (102), a plurality of groups of auxiliary synchronous wheels (104) are rotationally connected to the inner wall of the shell (101), a plurality of groups of auxiliary synchronous wheels (104) and the main synchronous wheel (102) are rectangular and distributed in the shell (101), two groups of synchronous belts (105) are sleeved on the outer wall of the main synchronous wheel (102) and the outer wall of the plurality of groups of auxiliary synchronous wheels (104), a driving motor (103) is fixedly connected to one end of the main synchronous wheel (102), two groups of microwave emitting devices (106) are fixedly connected to the bottom end of the inner wall of the shell (101), two groups of wave guide tubes (107) are respectively extended to the inner parts of one group of wave guide tubes (107), two groups of auxiliary air guide tubes (108) are fixedly connected to the bottom ends of the shell (101), two groups of auxiliary air guide tubes (108) are fixedly connected to the outer wall of the shell (101), one end of the auxiliary air guide tubes (108) is fixedly connected to one end of the shell (110), the inner wall of the air inlet pipe (110) is fixedly connected with an air suction motor (111) near the top end, the output end of the air suction motor (111) is fixedly connected with a fan (112) positioned in the air inlet pipe (110), the bottom ends of the air inlet pipe (110) are respectively communicated with two sides of the shell (101), the shell (101) is provided with an air inlet (113) at the communication position with the air inlet pipe (110), the top end of the shell (101) is communicated with an air outlet (120), the side wall of the shell (101) is provided with an observation window, and glass is fixed on the observation window;

The recycling mechanism (3) comprises a rotary table (301), the rotary table (301) is fixedly connected with the other end of a main synchronous wheel (102), the side wall of the rotary table (301) is rotationally connected with a connecting rod (302), the side wall of a shell (101) is fixedly connected with a lower bin body (303), the top end of the lower bin body (303) is communicated with an upper bin body (304), the side wall of the upper bin body (304) is communicated with one end of a pipeline (305), the other end of the pipeline (305) is communicated with the inside of an inner bin (114), the top end of the upper bin body (304) is communicated with a rubber sleeve (306), the top end of the rubber sleeve (306) is fixedly connected with a pressing plate (307), the top end of the pressing plate (307) is fixedly connected with the bottom end of the connecting rod (302), the upper bin body (304) is provided with a first one-way valve (312) at the position communicated with the pipeline (305), the top end of the lower bin body (303) is provided with a second one-way valve (313), the inner wall of the lower bin body (303) is fixedly connected with a cotton filter bank (310), the two groups of cotton filter banks (310) are connected with the bottom end of the lower bin (303) and the lower bin (310) is fixedly connected with a filter tank (310), the bottom end of the shell (101) is fixedly connected with a collecting box (309) positioned below the drain pipe (308).

2. The drying device for producing heat insulation material according to claim 1, wherein: the inner wall of air intake (113) is provided with inclination, interior storehouse (114) have been seted up to the inner wall of shell (101), multiunit opening (115) have been seted up to the lateral wall of interior storehouse (114), and multiunit opening (115) position corresponds with a set of air intake (113) respectively, the inner wall fixedly connected with multiunit heat-conducting plate (116) of interior storehouse (114), multiunit the lateral wall of heat-conducting plate (116) is a set of elastic sheet (117) of fixedly connected with respectively, the terminal fixedly connected with sheetmetal (118) of elastic sheet (117), two sets of hot-blast mouths (121) have been seted up on the top of interior storehouse (114).

3. The drying device for producing heat insulation material according to claim 1, wherein: the feed mechanism (2) comprises a bracket (201), two groups of brackets (201) are slidably connected to the side wall of the shell (101), two groups of fixed arms (202) are fixedly connected to the side wall of the synchronous belt (105), a grid frame (119) is arranged between the two groups of fixed arms (202) which are positioned at the same horizontal height, two groups of rectangular columns (1191) are fixedly connected to the side wall of the grid frame (119), and the two groups of rectangular columns (1191) are slidably connected to the inside of the group of fixed arms (202) respectively.

4. A drying apparatus for producing a heat insulating material according to claim 3, wherein: the bracket (201) comprises a sliding block (2011), the sliding block (2011) is slidably connected to the side wall of the shell (101), a cover plate (2012) is fixedly connected to the top end of the sliding block (2011), a support (2013) extending to the inside of the shell (101) is fixedly connected to the side wall of the sliding block (2011), two groups of grooves (2014) are formed in the top end of the support (2013), two groups of inclined blocks (2015) are fixedly connected to the outer wall of the support (2013) beside the two groups of grooves (2014) respectively, and a plurality of groups of sliding grooves (2016) are formed in the bottom ends of the inclined blocks (2015) respectively.

5. The drying device for producing heat insulation material according to claim 4, wherein: the fixed arm (202) comprises a support arm (2021), one end of the support arm (2021) is fixedly connected to the side wall of the synchronous belt (105), the other end of the support arm (2021) is fixedly connected with a fixed block (2022), the inner wall of the fixed block (2022) is slidably connected with a plurality of groups of limiting blocks (2023) extending to the outer part of the fixed block (2022), the inner walls of two groups of limiting blocks (2023) located above are slidably connected with a group of sliding plates (2024) extending to the outer part of the limiting blocks (2023) respectively, the thickness of the sliding plates (2024) is identical to that of the sliding grooves (2016), and the top end of the fixed block (2022) is fixedly connected with two groups of guide plates (2027).

6. The drying device for producing heat insulation material according to claim 5, wherein: the limiting block (2023) is located one end fixedly connected with first reset spring (2025) inside the fixed block (2022), the end fixedly connected with of first reset spring (2025) is at the inner wall of fixed block (2022), one end fixedly connected with second reset spring (2026) inside sliding plate (2024) is located limiting block (2023), the end fixedly connected with of second reset spring (2026) is at the inner wall of limiting block (2023).