CN210198000U - Nano material radiation drying equipment - Google Patents

Abstract

The utility model discloses a nano-material radiation drying equipment, including the drying cabinet, its characterized in that, the rotation is connected with two pay-off belts in the drying cabinet, and two pay-off belts crisscross settings from top to bottom, the rotation opposite direction of two pay-off belts is equipped with linkage structure between two pay-off belts, is provided with a material import and a material export on the drying cabinet, and the interlude has the radiant tube in the drying cabinet, and the radiant tube is connected with the hot-water tank, is connected with the hot-water pump on the radiant tube, has seted up air intake and air outlet on the drying cabinet respectively, and air intake and air outlet are connected. Which can improve the drying effect.

Description

Nano material radiation drying equipment

Technical Field

The utility model relates to a nano-material equipment, concretely relates to nano-material radiation drying equipment.

Background

The nano-scale structural material is referred to as nano material, and the size of the structural unit is between 1 nanometer and 100 nanometers. Since its size is already close to the coherence length of the electrons, its properties vary greatly due to self-organization by strong coherence. Moreover, its dimensions are close to the wavelength of light, plus it has the special effect of a large surface, so that its properties, such as melting point, magnetic, optical, thermal, electrical conductivity, etc., are often different from the properties that the substance exhibits in its bulk state. The nano material is mostly made of various materials, is cut into tiny particles, is mixed, dried, cooled and the like, and is hot-pressed and molded into a finished product in the subsequent process.

In the existing drying equipment, the nanometer material is generally conveyed through a belt, the nanometer material enters the equipment from a feed inlet along with the rotation of the belt, then the nanometer material leaves the equipment from a discharge outlet, and a heater is arranged in the equipment to heat and dry the nanometer material on the belt.

Although the drying equipment can dry the nano material, the belt moving speed is high, the drying time of the nano material on the belt by the heater is short, and the drying effect is not obvious.

Disclosure of Invention

In order to overcome the deficiencies in the prior art, the utility model provides a nano-material radiation drying equipment, it can improve dry effect.

In order to realize the above-mentioned purpose, the utility model discloses a nano-material radiation drying equipment, including the drying cabinet, its characterized in that, it is connected with two pay-off belts to rotate in the drying cabinet, crisscross setting from top to bottom in two pay-off belts, the rotation opposite direction of two pay-off belts, be equipped with linkage structure between two pay-off belts, be provided with a material import and a material export on the drying cabinet, the interlude has the radiant tube in the drying cabinet, the radiant tube is connected with the hot-water tank, be connected with the heat-water pump on the radiant tube, air intake and air outlet have been seted up on the drying cabinet respectively, air intake.

Furthermore, a plurality of radiating bodies are integrally arranged on the radiating tube, and each radiating body is spiral.

Further, linkage structure is including rotating two first pivots of connection in one of them pay-off area inboard respectively, coaxial coupling has first gear in one of them first pivot, first pivot is rotated with the inner wall of drying cabinet and is connected, the inner wall of drying cabinet rotates and is connected with first idler and second idler, first idler and second idler are coaxial fixed, first idler and first gear engagement, the inboard of another pay-off area is equipped with two second pivots, two second pivots rotate with the inner wall of drying cabinet and are connected, the common cover in the outside of one of them second pivot and second idler is equipped with the belt, one of them first pivot coaxial coupling has the motor.

Further, the belt slope sets up, and sliding connection has the slide on the inner wall of drying cabinet, and the slide extends the outside of drying cabinet, rotates on the slide to be connected with the pinch roller, and the pinch roller is contradicted with the belt and is cooperated, and the outside of drying cabinet is fixed with the cylinder, the piston rod and the slide fixed connection of cylinder.

Further, the two feeding belts are obliquely arranged.

Furthermore, the end parts of the two feeding belts are provided with material bearing plates which are fixedly connected with the inner wall of the drying box.

Has the advantages that: 1. the nanometer material moves from the feeding belt on the upper side and falls on the feeding belt on the lower side, so that the moving distance and moving time of the nanometer material are improved, and the drying effect of the nanometer material is improved;

2. the fan improves air flow rate in the drying box and improves the drying effect of the nano material.

Drawings

The invention will be further described and illustrated with reference to the accompanying drawings.

FIG. 1 is a schematic view of the mechanism of the embodiment as a whole;

fig. 2 is an enlarged view at a in fig. 1.

Reference numerals: 1. a drying oven; 2. a feed belt; 3. a linkage structure; 31. a first rotating shaft; 32. a first gear; 33. a first idler pulley; 34. a second idler pulley; 35. a second rotating shaft; 36. a belt; 37. a motor; 4. a material inlet; 5. a material outlet; 6. a radiant tube; 7. a hot water tank; 8. a hot water pump; 9. an air inlet; 10. an air outlet; 11. a fan; 12. a radiator; 13. a slide plate; 14. a pinch roller; 15. a cylinder; 16. a material bearing plate.

Detailed Description

The technical solution of the present invention will be more clearly and completely explained by the description of the preferred embodiments of the present invention with reference to the accompanying drawings.

Example (b): nanometer material radiation drying equipment, including drying cabinet 1, be equipped with two pay-off belts 2 in the drying cabinet 1, two pay-off belts 2 height settings, two pay-off belts 2 all incline to the left, and the left end of the pay-off belt 2 that is in the high side is material inlet 4, and the left end of the pay-off belt 2 that is in the bottom side is material outlet 5, and the direction of rotation of two pay-off belts 2 is opposite. The nano material is conveyed to the right side by the high-side material conveying belt 2 and falls on the right side of the low-side material conveying belt 2 from the right side of the high-side material conveying belt 2, a material bearing plate 16 is installed on the right side of the low-side material conveying belt 2 and used for bearing the falling nano material, the nano material is conveyed to the left side by the low-side material conveying belt 2, and finally the nano material slides out of the drying box 1 from the left-side material outlet 5.

As shown in fig. 1 and 2, a linkage structure 3 is arranged between the two feeding belts 2, and the linkage structure 3 is used for driving the two feeding belts 2 to rotate oppositely. This linkage structure 3 is including fixing the motor 37 on 1 outer wall of drying cabinet, and during drying cabinet 1 was stretched into to the pivot of motor 37, motor 37 and one of them cup jointed the first pivot 31 coaxial coupling in high side material feeding area 2 inboard, motor 37 and high side material feeding area 2 synchronous revolution. The other first rotating shaft 31 is coaxially connected with a first gear 32, the first gear 32 is positioned at the outer side of the drying box 1, a first idle gear 33 and a second idle gear 34 are rotatably connected on the drying box 1, the first idle gear 33 and the second idle gear 34 are coaxially fixed, the first idle gear 33 and the second idle gear 34 are also positioned at the outer side of the drying box 1, and the first idle gear 33 is meshed with the first gear 32. The second idle pulley 34 is connected with a second rotating shaft 35 sleeved on the inner side of the bottom side feeding belt 2 through a belt 36, the belt 36 is sleeved on the outer sides of the second idle pulley 34 and the second rotating shaft 35, and the belt 36 is positioned on the outer side of the drying box 1.

As shown in fig. 1, a heater is provided at the bottom side of the drying box 1 to heat and dry the nanomaterial, and the heater dries the nanomaterial while the nanomaterial moves on the feeding belt 2. The heater is including setting up hot-water tank 7 in the drying cabinet 1 outside, and hot-water tank 7 passes through radiant tube 6 to be connected in the inboard of drying cabinet 1, is connected with hot-water pump 8 on the radiant tube 6, and hot-water pump 8's input and output are connected with hot-water tank 7 through radiant tube 6 respectively. The hot water tank 7 is stored with water, the water is heated through the heating wire, the hot water pump 8 pumps the hot water into the drying box 1, and then the hot water generates heat radiation to perform radiation drying on the nano materials on the two layers of feeding belts 2. The radiator tube 6 is provided with a plurality of radiators 12, the radiators 12 are spiral, and the radiators 12 are communicated with the radiator tube 6. The spiral shape of the radiator 12 increases the area of the radiation tube 6 in the drying box 1, so that the radiator 12 heats the nanomaterial in the drying box 1 more easily.

As shown in fig. 1, an air inlet 9 and an air outlet 10 are arranged on the top side of the drying box 1, the air inlet 9 and the air outlet 10 are connected with a fan 11 together, air in the drying box 1 is continuously pumped into the fan 11 for cooling and then pumped into the air inlet 9, and original hot air in the drying box 1 is circularly cooled in the operation process of the fan 11.

As shown in fig. 1 and 2, during the process of the second idler 34 continuously moving the low side feed belt 2 by the belt 36, the rotation of the low side feed belt 2 is not flexible due to the slack of the belt 36. Thus, an air cylinder 15 for tensioning the belt 36 is fixed on the outside of the drying box 1, a slide 13 is fixed on the piston rod of the air cylinder 15, the slide 13 slides longitudinally on the outer wall of the drying box 1, a part of the slide 13 extends into the drying box 1, and the part of the slide 13 slides relative to the inner wall of the drying box 1, and a pinch roller 14 is rotatably connected on the slide 13. After the piston rod of the cylinder 15 extends, the cylinder 15 can drive the pressing wheel 14 to abut against the surface of the belt 36, the belt 36 is tightened due to the abutting force, and the belt 36 is obliquely arranged along the right offset of the vertical axis, so that the pressing wheel 14 and the belt 36 abut against and are pressed tightly.

The operation process is as follows:

the motor 37 drives the feeding belt 2 on the top side to rotate through the first rotating shaft 31, the first rotating shaft 31 drives the first idle pulley 33 and the second idle pulley 34 to rotate simultaneously, and the second idle pulley 34 drives the feeding belt 2 on the bottom side to rotate through the belt 36, so that the rotation directions of the two feeding belts 2 are opposite.

The above detailed description merely describes the preferred embodiments of the present invention and does not limit the scope of the present invention. Without departing from the design concept and spirit scope of the present invention, the ordinary skilled in the art should belong to the protection scope of the present invention according to the present invention provides the text description and drawings to the various modifications, replacements and improvements made by the technical solution of the present invention. The scope of protection of the present invention is determined by the claims.

Claims (6)

1. Nanometer material radiation drying equipment, including drying cabinet (1), its characterized in that, swivelling joint has two pay-off areas (2) in drying cabinet (1), two pay-off area (2) crisscross setting from top to bottom, two the rotation direction of pay-off area (2) is opposite, two be equipped with linkage structure (3) between pay-off area (2), be provided with a material import (4) and a material export (5) on drying cabinet (1), alternate in drying cabinet (1) and have radiant tube (6), radiant tube (6) are connected with hot-water tank (7), be connected with hot-water pump (8) on radiant tube (6), air intake (9) and air outlet (10) have been seted up respectively on drying cabinet (1), air intake (9) and air outlet (10) are connected with fan (11) jointly.

2. The nanomaterial radiant drying device according to claim 1, characterized in that a plurality of radiators (12) are integrally arranged on the radiant tube (6), each radiator (12) having a spiral shape.

3. The nanomaterial radiation drying apparatus according to claim 1, characterized in that the linkage structure (3) comprises two first rotating shafts (31) rotatably connected to the inner side of one of the feeding belts (2), respectively, wherein one of the first rotating shafts (31) is coaxially connected with a first gear (32), the first rotating shaft (31) is rotatably connected with the inner wall of the drying box (1), the inner wall of the drying box (1) is rotatably connected with a first idler (33) and a second idler (34), the first idler (33) and the second idler (34) are coaxially fixed, the first idler (33) is meshed with the first gear (32), the inner side of the other feeding belt (2) is provided with two second rotating shafts (35), the two second rotating shafts (35) are rotatably connected with the inner wall of the drying box (1), wherein the outer sides of one of the second rotating shafts (35) and the second idler (34) are jointly sleeved with a belt (36), one of the first rotating shafts (31) is coaxially connected with a motor (37).

4. The nanomaterial radiation drying apparatus according to claim 3, wherein the belt (36) is obliquely arranged, a sliding plate (13) is slidably connected to an inner wall of the drying oven (1), the sliding plate (13) extends out of the outside of the drying oven (1), a pressing wheel (14) is rotatably connected to the sliding plate (13), the pressing wheel (14) is in interference fit with the belt (36), an air cylinder (15) is fixed to the outside of the drying oven (1), and a piston rod of the air cylinder (15) is fixedly connected to the sliding plate (13).

5. Nanomaterial radiation drying apparatus according to claim 3, characterized in that the two feeding belts (2) are arranged inclined.

6. The nanomaterial radiation drying apparatus of claim 3, characterized in that the end parts of the two feeding belts (2) are provided with material bearing plates (16), and the material bearing plates (16) are fixedly connected with the inner wall of the drying oven (1).

Images