CN210663733U - Energy-conserving drying device of high-efficient activated clay - Google Patents

Abstract

The utility model discloses a high-efficiency energy-saving activated clay drying device, which belongs to the technical field of drying devices and comprises a drying machine body, wherein thermal resistance wires are arranged on the inner side wall of the drying machine body, a large-size screen mesh, a medium-size screen mesh and a small-size screen mesh are sequentially arranged in the drying machine body from top to bottom, a pressing shovel can preliminarily press and crush massive clay at the top of the large-size screen mesh, a scraping and brushing nail can continuously scrape and loosen the activated clay on the medium-size screen mesh and the small-size screen mesh to prevent the activated clay from being condensed into blocks in the drying process, the thermal resistance wires and an injection pipe can accelerate the air flow speed in the drying machine body, an exhaust fan can discharge hot and humid air in the machine body into a heat pump through a pipeline, moisture in the high-humidity hot air is cooled into liquid distilled water through the method of the heat pump, and the heat is discharged into the drying machine body through the pipeline, and resources are saved.

Description

Energy-conserving drying device of high-efficient activated clay

Technical Field

The utility model relates to a drying device technical field especially relates to an energy-conserving drying device of high-efficient activated clay.

Background

The activated clay is an adsorbent which is prepared by taking bentonite as a raw material through multiple processes, is white and tasteless in appearance, has low manufacturing cost and strong adsorption performance, can adsorb colored substances and organic substances, is widely used in a plurality of industrial fields, is easy to absorb moisture in the air, and has poor adsorption capacity after moisture absorption, so the activated clay needs to be dried before use, the existing activated clay drying device only can be used for single integral drying, needs long time and has poor drying effect, reduces the production rate of the activated clay, the activated clay with serious moisture absorption is easy to be condensed into blocks, a common drying device cannot effectively loosen the activated clay, the drying is uneven, the adsorption effect of the activated clay is reduced, and the existing drying device cannot recycle the air with waste heat generated by drying, the heat waste is very serious, which causes serious waste of electric resources and simultaneously increases the production cost.

A high-efficient activated clay energy-saving drying device who publishes in patent number CN 208620773U passes through the rotary rod, the carousel, scrape and brush palladium nail, can last scraping the brush to activated clay on the carousel, turn over the pine, the activated clay that avoids the moisture absorption condenses into the piece, it is more even to make steam stoving, the dry speed has been improved, and the device installs the air pump, the air duct, induction port and air outlet nozzle, absorb the moisture in the hot and humid air through the cotton that absorbs water, steam emits into drying device circulation and uses, thereby thermal waste has been avoided, save electric resource.

The activated clay energy-saving drying device disclosed in the patent number has the following defects: 1. the activated clay energy-saving drying device disclosed in the patent number only depends on the scraping and brushing palladium nails to continuously scrape and brush the activated clay on the rotating disc and turn the activated clay to prevent the activated clay from being condensed into blocks, a plurality of activated clays before drying are condensed into larger blocks, the block-shaped activated clay cannot be crushed only depending on the scraping and brushing force of the scraping and brushing palladium nails, and the block-shaped activated clay can be clamped inside the drying device to influence the further drying work; 2. the activated clay energy-saving drying device disclosed in the patent number only blows hot air to the activated clay to be dried through the air outlet nozzle by means of the heater, so that the activated clay is dried, the drying speed is low, and the production efficiency is reduced; 3. the activated clay energy-saving drying device disclosed in the patent number only absorbs moisture in hot and humid air through the water absorption cotton, the air carrying waste heat enters the installation pipe again through the air guide pipe and the air outlet pipe for recycling, the water absorption capacity of the water absorption cotton is limited, during the production process, a large amount of hot and humid air can be generated by drying the activated clay, a large amount of moisture is carried in the hot and humid air, when the absorption capacity of the water absorption cotton is insufficient, the hot and humid air can flow into the drying device again from the circulation system, the moisture in the drying device cannot be discharged, and when the humidity reaches a certain degree, the drying speed is reduced or even the drying cannot be performed; therefore, an efficient activated clay energy-saving drying device is provided.

SUMMERY OF THE UTILITY MODEL

The utility model provides a high-efficient activated clay energy-saving drying device, the top of a large-size screen sieve is connected with a pressing shovel, an electric telescopic rod can drive the pressing shovel to move up and down mechanically through expansion, the massive clay at the top of the large-size screen sieve is pressed and crushed preliminarily, the scraping brush palladium nail can continuously scrape and brush the activated clay on a medium-size screen sieve and a small-size screen sieve, the activated clay is prevented from being condensed into blocks in the drying process, a thermal resistance wire on the inner side wall of a drying machine body can rapidly dry the activated clay through a heating mode, a strong wind is blown out from a vacuum pump through a jetting pipe to accelerate the flowing speed of airflow in the drying machine body, the drying speed of the activated clay is further increased, a hot and humid air in the drying machine body can be discharged into a heat pump through a pipeline by an exhaust fan, moisture in the high-humid hot air is cooled into liquid distilled water through a heat pump method, meanwhile, the, and resources are saved.

The utility model provides a specific technical scheme as follows:

the utility model provides a high-efficiency activated clay energy-saving drying device, which comprises a drying machine body, wherein the inner side wall of the drying machine body is provided with a thermal resistance wire, a large-size screen sieve, a medium-size screen sieve and a small-size screen sieve are sequentially arranged in the dryer body from top to bottom, the top of the large-size screen sieve is connected with a pressing shovel, the power input end of the pressing shovel is electrically connected with the power output end of the electric telescopic rod, scraping and brushing palladium nails and an injection pipe are arranged at the tops of the medium-sized and small-sized filter screens, the scraping and brushing palladium nails and the injection pipe are both arranged on the surfaces of the fixed support rods, the power input end of the blowing pipe is electrically connected with the power output end of the vacuum pump, a plurality of exhaust fans are installed at the top end of the dryer body, the air outlet of the exhaust fan is connected with the air inlet of the heat pump through a pipeline, and the air outlet of the heat pump is connected with the air inlet of the drying machine body through a pipeline.

Optionally, the dryer body is fixedly mounted at the top end of the support.

Optionally, a feed inlet is formed in the top of the dryer body, a discharge outlet is formed in the bottom of the dryer body, and the feed inlet and the discharge outlet are both connected with the sealing cover.

Optionally, the outer side wall of the dryer body is sprayed with electrostatic powder.

Optionally, the power input ends of the large-size screen mesh, the medium-size screen mesh and the small-size screen mesh are electrically connected with the power output end of the motor through the stirring shaft

The utility model has the advantages as follows:

the embodiment of the utility model provides an energy-conserving drying device of high-efficient activated clay:

1. the large-size screen mesh top with press down the shovel and be connected, the flexible drive of electric telescopic handle accessible presses down shovel up-and-down mechanical motion, tentatively presses the cubic carclazyte at large-size screen mesh top and smashes, scrapes the brush palladium nail and can continuously scrape the brush, turn over the pine with activated clay on medium-size screen mesh and the small-size screen mesh, prevent the caking that condenses among the drying process, solve the limited problem of the energy-conserving drying device crushing capacity of activated clay that publishes in the above-mentioned patent number.

2. The mode of hot resistance silk accessible heating of drying-machine body inside wall is dried activated clay fast, and the vacuum pump blows off the high wind through the jetting pipe, and the inside air current flow velocity of drying-machine body is accelerated, further increases activated clay stoving speed, solves the slow problem of activated clay energy-conserving drying device stoving speed of the active clay who publishes in above-mentioned patent number.

3. The exhaust fan can be with the inside hot humid air of organism through the pipeline arrange the heat pump in, through the method of heat pump, the moisture cooling is liquid distilled water in the hot humid air of high humidity, simultaneously with the heat through the inside waste heat utilization that realizes of pipeline arrange the drying-machine body, resources are saved solves the problem that the moisture in the unable complete processing humid hot air of the energy-conserving drying device waste heat utilization system of active carclazyte who publishes in the above-mentioned patent number can influence drying device's stoving speed.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic view of the overall structure of an energy-saving efficient activated clay drying device in an embodiment of the present invention;

fig. 2 is a schematic structural view of a medium-sized mesh screen of the energy-saving drying device for high-efficiency activated clay in the embodiment of the present invention;

fig. 3 is a schematic circuit diagram of an energy-saving drying device for high-efficiency activated clay according to an embodiment of the present invention.

In the figure: 1. a dryer body; 2. a thermal resistance wire; 3. fixing the supporting rod; 4. a support; 5. a feed inlet; 6. an electric telescopic rod; 7. pressing the shovel; 8. an exhaust fan; 9. a pipeline; 10. a large-size screen mesh; 11. a medium-sized screen mesh; 12. a small-size screen mesh; 13. a heat pump; 14. a discharge port; 15. an electric motor; 16. a stirring shaft; 17. scraping and brushing the palladium nails; 18. a blowing pipe; 19. a vacuum pump.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the present invention will be described in further detail with reference to the accompanying drawings, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

The following will explain in detail a high-efficiency activated clay energy-saving drying device according to an embodiment of the present invention with reference to fig. 1 to 3.

Referring to fig. 1 and 2, an energy-saving drying device for activated clay provided by an embodiment of the present invention comprises a drying machine body 1, wherein a thermal resistance wire 2 is installed on an inner side wall of the drying machine body 1, a large-size screen sieve 10, a medium-size screen sieve 11 and a small-size screen sieve 12 are sequentially installed inside the drying machine body 1 from top to bottom, the top of the large-size screen sieve 10 is connected with a pressing shovel 7, a power input end of the pressing shovel 7 is electrically connected with a power output end of an electric telescopic rod 6, the tops of the medium-size screen sieve 11 and the small-size screen sieve 12 are provided with a scraping palladium nail 17 and an injection pipe 18, the scraping palladium nail 17 and the injection pipe 18 are both installed on the surface of a fixed support rod 3, a power input end of the injection pipe 18 is electrically connected with a power output end of a vacuum pump 19, a plurality of exhaust fans 8 are installed on the top end of the drying machine body 1, an air outlet of each, and an air outlet of the heat pump 13 is connected with an air inlet of the dryer body 1 through a pipeline 9.

Illustratively, the top of a large-size screen sieve 10 is connected with a pressing shovel 7, an electric telescopic rod 6 can drive the pressing shovel 7 to move up and down mechanically through expansion and contraction, massive argil at the top of the large-size screen sieve 10 is pressed and crushed preliminarily, a scraping and brushing palladium nail 17 can continuously scrape and brush and loosen activated argil on a medium-size screen sieve 11 and a small-size screen sieve 12 to prevent the activated argil from being condensed into blocks in the drying process, a thermal resistance wire 2 on the inner side wall of a drying machine body 1 can rapidly dry the activated argil in a heating mode, a vacuum pump 19 blows out strong wind through an injection pipe 18 to accelerate the flow speed of airflow inside the drying machine body 1, the drying speed of the activated argil is further increased, a ventilating fan 8 can discharge hot and humid air inside the machine body into a heat pump 13 through a pipeline 9, moisture in the hot and humid air is cooled into liquid distilled water through the method of the heat pump 13, and heat is discharged into the drying machine, and resources are saved.

Referring to fig. 1, the dryer body 1 is fixedly installed at the top end of a support 4.

By way of example, the drying machine body 1 is fixedly installed at the top end of the support 4, and is convenient and practical.

Referring to fig. 1, a feed inlet 5 is formed at the top of the dryer body 1, a discharge outlet 14 is formed at the bottom of the dryer body 1, and the feed inlet 5 and the discharge outlet 14 are both connected with a sealing cover.

In the example, the feeding port 5 is convenient for feeding materials into the drying device for drying, the discharging port 14 is convenient for taking out the completely dried materials, and the sealing cover increases the sealing effect.

Referring to fig. 1, the outer sidewall of the dryer body 1 is sprayed with electrostatic powder.

Illustratively, the electrostatic powder prevents corrosion and rust, and increases the service life of the dryer body 1.

Referring to fig. 1, the power input ends of the large-size screen 10, the medium-size screen 11 and the small-size screen 12 are electrically connected to the power output end of the motor 15 through a stirring shaft 16.

Illustratively, the motor 15 can drive the stirring shaft 16 to rotate to drive the large-size screen mesh 10, the medium-size screen mesh 11 and the small-size screen mesh 12 to rotate, so as to facilitate the screening of the activated clay.

When the drying machine is used, a worker puts activated clay to be dried into the drying machine body 1 from the feeding hole 5, an external power supply supplies power, the thermal resistance wire 2, the electric telescopic rod 6, the exhaust fan 8, the heat pump 13, the motor 15 and the vacuum pump 19 are opened through an external switch, the thermal resistance wire 2 heats and dries the activated clay (the model of the thermal resistance wire 2 is Cr20Ni80), the vacuum pump 19 blows strong wind (the model of the vacuum pump 19 is 2X-4G) through the injection pipe 18, the flowing speed of airflow in the drying machine body 1 is accelerated, the drying speed of the activated clay is further increased, the motor 15 drives the large-size screen sieve 10, the medium-size screen sieve 11 and the small-size screen sieve 12 to rotate (the model of the motor 15 is YS5624) through the stirring shaft 16, the electric telescopic rod 6 can drive the pressing shovel 7 to move up and down through stretching (the model of the electric telescopic rod 6 is wxtg, the crushed activated clay leaks to the surface of a medium-sized screen 11 through large filter holes on the surface of a large-sized screen 10, the scraping and brushing palladium nails 17 can continuously scrape and loosen the activated clay on the medium-sized screen 11 and a small-sized screen 12 to prevent the activated clay from being coagulated into blocks in the drying process, the dried activated clay leaks to a discharge hole 14 from the filter holes on the surface of the small-sized screen 12, the damp and hot air in the drying process is discharged by an exhaust fan 8 (the model of the exhaust fan 8 is FA-30), the exhaust fan 8 transmits the damp and hot air to a heat pump 13 (the model of the heat pump 13 is RE-200L3-U1) through a pipeline 9, the water in the damp and hot air is cooled into liquid distilled water by the method of the heat pump 13, and the heat is discharged into a drying machine body 1 through the pipeline 9 to realize waste heat utilization, thereby saving resources.

The utility model relates to a high-efficiency active clay energy-saving drying device, which comprises a drying machine body 1; 2. a thermal resistance wire; 3. fixing the supporting rod; 4. a support; 5. a feed inlet; 6. an electric telescopic rod; 7. pressing the shovel; 8. an exhaust fan; 9. a pipeline; 10. a large-size screen mesh; 11. a medium-sized screen mesh; 12. a small-size screen mesh; 13. a heat pump; 14. a discharge port; 15. an electric motor; 16. a stirring shaft; 17. scraping and brushing the palladium nails; 18. a blowing pipe; 19. the vacuum pump and the components are all standard parts or parts known to those skilled in the art, and the structure and principle of the vacuum pump and the components are known to those skilled in the art through technical manuals or through routine experiments.

It is apparent that those skilled in the art can make various changes and modifications to the embodiments of the present invention without departing from the spirit and scope of the embodiments of the present invention. Thus, if such modifications and variations of the embodiments of the present invention fall within the scope of the claims and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (5)

1. An efficient energy-saving activated clay drying device comprises a drying machine body (1) and is characterized in that a thermal resistance wire (2) is mounted on the inner side wall of the drying machine body (1), a large-size screen sieve (10), a medium-size screen sieve (11) and a small-size screen sieve (12) are sequentially mounted in the drying machine body (1) from top to bottom, the top of the large-size screen sieve (10) is connected with a pressing shovel (7), the power input end of the pressing shovel (7) is electrically connected with the power output end of an electric telescopic rod (6), scraping and brushing palladium nails (17) and an injection pipe (18) are mounted at the tops of the medium-size screen sieve (11) and the small-size screen sieve (12), the scraping and brushing palladium nails (17) and the injection pipe (18) are mounted on the surface of a fixed support rod (3), and the power input end of the injection pipe (18) is electrically connected with the power output end of a vacuum pump, a plurality of exhaust fan (8) are installed on drying-machine body (1) top, the air outlet of exhaust fan (8) passes through the air intake connection of pipeline (9) and heat pump (13), the air outlet of heat pump (13) passes through the air intake connection of pipeline (9) and drying-machine body (1).

2. The energy-saving efficient activated clay drying device as claimed in claim 1, wherein said drying machine body (1) is fixedly installed on top of the bracket (4).

3. The energy-saving drying device for activated clay as claimed in claim 1, wherein the top of the drying machine body (1) is opened with a feeding port (5), the bottom of the drying machine body (1) is opened with a discharging port (14), and the feeding port (5) and the discharging port (14) are both connected with a sealing cover.

4. The energy-saving efficient activated clay drying device as claimed in claim 1, wherein the outer wall of the dryer body (1) is coated with electrostatic powder.

5. The energy-saving drying device for high-efficiency activated clay according to claim 1, characterized in that the power input ends of the large-size screen mesh (10), the medium-size screen mesh (11) and the small-size screen mesh (12) are electrically connected with the power output end of the motor (15) through a stirring shaft (16).

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