CN210560888U - Calotropis gigantean fiber extraction device - Google Patents

Abstract

A cowberry fruit fiber extraction element, there are first fresh air inlet and first air outlet used for connecting the air-out end of the blast apparatus on the microwave box; a microwave generator and a rotating shaft are arranged in the microwave box; the rotating shaft is in transmission connection with the driving device and is connected with the rotating tray; an explosion-proof mesh enclosure is arranged above the rotary tray; the first mesh plate and the second mesh plate are arranged in the composite fiber collecting box and are used for sequentially dividing the interior of the composite fiber collecting box into a first filtering bin, a second filtering bin and a collecting bin; a second air inlet hole on the first filter bin is connected with the first air outlet hole; the second air outlet hole on the collecting bin is connected with the air inlet end of the air suction device. The utility model discloses the application method of calotropis gigantea fibre extraction element has still been provided. The utility model discloses an effect of microwave makes the inside hydrone high-speed motion of calotropis gigantea fruit, produces atmospheric pressure and makes the fruit blasting, later inhales the combined type fibre collecting box with the fibre through blast apparatus and the device that induced drafts to carry out effective separation with the fibre and obtain pure calotropis gigantea fibre.

Description

Calotropis gigantean fiber extraction device

Technical Field

The utility model relates to a calotropis gigantea fibre draws technical field, especially relates to a calotropis gigantea fibre extraction element.

Background

The mudar floss is a natural plant fiber growing from the seed crown hair of the mudar fruit, and is a novel textile fiber raw material to be developed. The mudar and cotton belong to the same seed fiber, but the methods for obtaining the mudar fiber and the cotton fiber are completely different, fresh fruits need to be picked for obtaining the mudar fiber, and the fresh fruits need to be dried and cracked to be convenient for separating the fiber from shells, seeds and sacs. The calotropis gigantea fiber has strong adhesive force with the seeds and the capsules, and the dried vegetal capsule pieces are easy to crack and adhere to the fiber, are not easy to separate and bring difficulty to the extraction and purification of the fiber; the mudar floss has the characteristics of low strength, fragility and frangibility, a thin-wall large-hollow structure, light weight and easy floating, and vegetal capsule pieces are easy to crack, and the mechanical external force beating for removing impurities is easy to cause the breakage of the fiber and the capsule.

Chinese patent No. CN203065661U discloses a special impurity removing device for separating calotropis gigantea fiber sacs and seeds for spinning, which is used for solving the problem that the separation of calotropis gigantea fibers, sacs and seeds is difficult; the device utilizes the physical mass difference of the fiber capsule seeds to separate and remove impurities by adopting air flow, but the device still needs to hold a metal sheet beater for a cotton feeding roller to remove impurities when in use, the impurity content of the obtained fibers is about 3 percent, the fibers can be damaged by beating, and the fibers with high purity and high quality cannot be obtained.

Chinese patent No. CN203393269U, discloses a mudar floss separating device for extracting mudar floss; the device adopts stoving, broken shell and fibre separation technique to obtain the high fibre of cleanliness factor, and above-mentioned device uses the interact of broken shell main shaft and broken shell claw, and mechanical broken shell is efficient and can not cut off the fibre, but the too much meeting of interact causes scraping and wearing and tearing to the fibre in the broken shell section of thick bamboo, influences fiber quality, is unfavorable for final spinning and surface fabric and weaves.

The conventional cotton plucking, ginning, seed cleaning and skin cleaning equipment is not suitable for the extraction and purification of mudar fibers. At present, the textile industry mainly adopts a manual stripping and extracting mode to extract the calotropis gigantea fibers, the method wastes time and labor, the impurity removal efficiency is low, and the extracted calotropis gigantea fibers are poor in quality.

SUMMERY OF THE UTILITY MODEL

Objects of the invention

For solving the technical problem who exists among the background art, the utility model provides a calotropis gigantea fibre extraction element, the utility model discloses an effect of microwave makes the inside hydrone high-speed motion of calotropis gigantea fruit, produces atmospheric pressure and makes the fruit explode, later inhales the combined type fibre collecting box with the fibre through blast apparatus and the device that induced drafts to carry out effective separation with the fibre and obtain pure calotropis gigantea fibre.

(II) technical scheme

The utility model provides a cow-horn melon fiber extraction device, which comprises an air blowing device, a microwave box, a rotary tray, a driving device, an acoustic control sensor, a fiber collecting pipe, a composite fiber collecting box, an air suction device and a controller;

a first air inlet hole and a first air outlet hole are formed in the microwave box; a microwave generator is arranged in the microwave box, and a rotating shaft is rotatably arranged on the bottom surface in the microwave box; the first air inlet hole is connected with the air outlet end of the blowing device; the rotating shaft is in transmission connection with the driving device, the rotating shaft is perpendicular to the bottom surface of the microwave box, and the end surface of the rotating shaft, which is far away from the microwave box, is connected with the rotating tray;

the composite fiber collecting box and the microwave box are arranged side by side, and a first mesh plate and a second mesh plate are arranged in the composite fiber collecting box; the first mesh plate and the second mesh plate are distributed side by side and used for sequentially dividing the interior of the composite fiber collecting box into a first filtering bin, a second filtering bin and a collecting bin, and first filtering holes used for communicating the first filtering bin with the second filtering bin are uniformly formed in the first mesh plate; second filtering holes for communicating the second filtering bin with the collecting bin are uniformly formed in the second mesh plate; the diameter of each second filtering hole is not larger than that of each first filtering hole;

the first filter bin is provided with a second air inlet hole on the composite fiber collecting box; the second air inlet hole is connected with a pipe orifice at one end of the fiber collecting pipe; the pipe orifice at the other end of the fiber collecting pipe is connected with the first air outlet hole;

the collecting bin is provided with a second air outlet hole on the composite fiber collecting box; the second air outlet hole is connected with an air inlet end of the air suction device;

the signal output end of the sound control sensor is connected with the signal output end of the controller; and a plurality of signal output ends of the controller are respectively connected with the signal input end of the blowing device and the signal input end of the air suction device.

Preferably, the explosion-proof net cover is included; the anti-explosion net cover is arranged in the microwave box, the end face, facing the bottom face of the microwave box, of the anti-explosion net cover is tightly pressed against the bottom face of the microwave box, and an anti-explosion bin used for containing the rotary tray and the rotating shaft is formed by the inner wall of the anti-explosion net cover and the bottom face of the microwave box.

Preferably, a connecting pipe is included; and the pipe orifice at one end of the connecting pipe is connected with the air inlet end of the air suction device, and the pipe orifice at the other end of the connecting pipe is connected with the second air outlet hole.

Preferably, two microwave generators are provided; the two microwave generators are distributed at the top of the microwave box side by side, wherein the microwave generators are symmetrically arranged by taking the central axis of the first air outlet hole as the center.

Preferably, comprises a movable plate; the movable plate is provided with a first groove and a second groove in parallel; wherein, an opening is arranged on any end face of the composite fiber collecting box perpendicular to the first mesh plate;

the end face of the movable plate facing the opening of the composite fiber collecting box compresses the end face of the composite fiber collecting box; the first mesh plate is inserted into the first groove in a matching manner, and the end face, positioned in the first groove, of the first mesh plate presses the inner wall of the first groove; the second mesh plate is inserted into the second groove in a matching mode, and the end face, located in the first groove, of the second mesh plate presses the inner wall of the second groove.

The utility model discloses still provide a use method about calotropis gigantea fibre extraction element, including following specific step:

s1, spreading the calotropis gigantea fiber raw material to be extracted on a rotating tray in a microwave box;

s2, the driving device is electrified to operate to drive the rotating tray to rotate;

s3, the microwave generator is electrified to operate to carry out microwave blasting on the calotropis gigantea fiber raw material to obtain calotropis gigantea fibers, calotropis gigantea shells and calotropis gigantea capsule fragments;

s4, after the mudar floss raw material is blasted, the sound control sensor receives the blasting sound and sends the received signal to the controller, and the controller controls the air blowing device and the air suction device to be electrified and operated;

the blowing device blows air into the microwave box from the first air inlet, and the calotropis gigantea fibers and the light impurities float in the microwave box;

the air suction device pumps out the air in the microwave box and the composite fiber collecting box so that the interiors of the microwave box and the composite fiber collecting box are in negative pressure;

s5, the mudar floss and the light impurities enter the first filtering bin from the first air outlet hole, the fiber collecting pipe and the second air inlet hole in sequence under the drive of the airflow;

light impurities with different sizes are intercepted by the first mesh plate and the second mesh plate in sequence, and the calotropis gigantea fibers are finally collected in the collection bin;

s6, closing the blowing device, the driving device, the microwave generator and the air suction device;

pure calotropis gigantea fiber is collected in the collection bin, and impurities in the first filtering bin, the second filtering bin and the microwave box are cleaned.

Preferably, the operating power of the microwave generator in S3 is 500-900W, the frequency is 6000MHz, and the working time is 5-10 min.

Preferably, the speed of the wind blown into the microwave box in S4 is 0.1-0.5 m/S.

Preferably, the vacuum degrees in the microwave box and the composite fiber collecting box in S4 are all-300E700 mmHg; the air suction speed of the air suction device in S4 is 0.1-6.0 m³/s。

The above technical scheme of the utility model has following profitable technological effect:

in the utility model, the mudar floss raw material to be extracted is spread on a rotary tray in a microwave box; the microwave generator is electrified to operate to perform microwave blasting on the mudar fiber raw material, and meanwhile, the driving device operates to drive the rotating tray to rotate so as to enable the material in the rotating tray to be subjected to sufficient microwave action; the water in the fruits is evaporated by using the heat effect generated by microwave conversion and the internal and external pressure difference is generated to crack the fruits, so that the damage of fibers can be effectively controlled to be minimum by using the microwave effect to replace the mechanical external force effect;

after the mudar floss raw material is exploded, the blowing device is electrified to blow air into the microwave box, and the mudar floss and the light impurities float in the microwave box; meanwhile, the air suction device is electrified to operate, so that the interiors of the microwave box and the composite fiber collecting box are both in negative pressure; the calotropis gigantea fibers and light impurities enter the first filtering bin from the first air outlet hole, the fiber collecting pipe and the second air inlet hole in sequence under the drive of airflow; light impurities with different sizes are intercepted by the first mesh plate and the second mesh plate in sequence, and the calotropis gigantea fibers are finally collected in the collection bin; after the mudar fibers are extracted, the pure mudar fibers in the collecting bin are collected, and the mudar impurities in the first filtering bin, the second filtering bin and the microwave box are cleaned, so that the mudar fiber collecting device is simple to operate and convenient to use; the utility model discloses utilize the microwave blasting method to draw the fibrous efficient and with low costs of calotropis gigantea, can realize the high-quality calotropis gigantea fibre of large-scale production, be favorable to producing the calotropis gigantea face fabrics of high quality.

Drawings

Fig. 1 is the utility model provides a cantaloupe fibre extraction element's schematic structure diagram.

Fig. 2 is the utility model provides a locally enlarged structure schematic diagram of a department in cowberry fruit fibre extraction element.

Reference numerals: 1. a blowing device; 2. a microwave box; 3. a first air inlet hole; 4. an explosion-proof mesh enclosure; 5. rotating the tray; 6. a rotating shaft; 7. a drive device; 8. a voice-activated sensor; 9. a microwave generator; 10. a first air outlet; 11. a fiber collection tube; 12. a composite fiber collecting box; 13. a second air inlet hole; 14. a first filtration bin; 15. a first mesh plate; 151. a first filtering hole; 16. a second filtration bin; 17. a second mesh plate; 171. a second filtering hole; 18. a collection bin; 19. a second air outlet hole; 20. a connecting pipe; 21. an air suction device; 22. a movable plate.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in detail with reference to the accompanying drawings. It should be understood that the description is intended to be illustrative only and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

As shown in fig. 1-2, the utility model provides a cowberry fruit fiber extraction device, which comprises a blowing device 1, a microwave box 2, a rotary tray 5, a driving device 7, a sound control sensor 8, a fiber collecting pipe 11, a composite fiber collecting box 12, an air suction device 21 and a controller;

a first air inlet hole 3 and a first air outlet hole 10 are formed in the microwave box 2; a microwave generator 9 is arranged in the microwave box 2, and a rotating shaft 6 is rotatably arranged on the bottom surface in the microwave box 2; the first air inlet hole 3 is connected with the air outlet end of the blowing device 1; the rotating shaft 6 is in transmission connection with a driving device 7, the rotating shaft 6 is vertically arranged with the bottom surface of the microwave box 2, and the end surface of the rotating shaft 6 far away from the microwave box 2 is connected with the rotating tray 5; the driving device 7 operates to drive the rotary tray 5 to rotate so that the materials in the rotary tray 5 are subjected to sufficient microwave action;

further, the blowing device 1 is a fan; the driving device 7 adopts a variable frequency motor;

the composite fiber collecting box 12 and the microwave box 2 are arranged side by side, and a first mesh plate 15 and a second mesh plate 17 are arranged in the composite fiber collecting box 12; the first mesh plate 15 and the second mesh plate 17 are distributed side by side and used for sequentially dividing the interior of the composite fiber collecting box 12 into a first filtering bin 14, a second filtering bin 16 and a collecting bin 18, and the first mesh plate 15 is uniformly provided with first filtering holes 151 used for communicating the first filtering bin 14 with the second filtering bin 16; the second mesh plate 17 is uniformly provided with second filtering holes 171 for communicating the second filtering bin 16 with the collecting bin 18; wherein, the diameter of each second filtering hole 171 is not larger than the diameter of each first filtering hole 151;

the first filter bin 14 is provided with a second air inlet hole 13 on the composite fiber collecting box 12; wherein, the second air inlet hole 13 is connected with a pipe orifice at one end of the fiber collecting pipe 11; the other end pipe orifice of the fiber collecting pipe 11 is connected with the first air outlet hole 10;

the collection bin 18 is provided with a second air outlet hole 19 on the composite fiber collection box 12; wherein, the second air outlet 19 is connected with the air inlet end of the air suction device 21;

the signal output end of the sound control inductor 8 is connected with the signal output end of the controller; a plurality of signal output ends of the controller are respectively connected with a signal input end of the blowing device 1 and a signal input end of the air suction device 21;

the arranged sound control inductor 8 captures the explosion sound of the mudar fiber raw material during microwave explosion and sends the detected sound signal to the controller; the controller controls the blowing device 1 and the air suction device 21 to be electrified and operated, and the intelligent control does not need manual operation, so that the production efficiency is greatly improved.

In the utility model, the mudar floss raw material to be extracted is spread on the rotary tray 5 in the microwave box 2; the microwave generator 9 is electrified to operate to perform microwave blasting on the mudar fiber raw material, and simultaneously the driving device 7 operates to drive the rotating tray 5 to rotate so as to enable the material in the rotating tray 5 to be subjected to sufficient microwave action; after the mudar floss raw material is exploded, the sound control inductor 8 catches the explosion sound and sends the received signal to the controller; the controller controls the air blowing device 1 and the air suction device 21 to be electrified and operated; the blowing device 1 blows air into the microwave box 2, and the calotropis gigantea fibers and the light impurities float in the microwave box 2; meanwhile, the air suction device 21 pumps out the air in the microwave box 2 and the composite fiber collecting box 12 so that the insides of the microwave box 2 and the composite fiber collecting box 12 are both negative pressure; the calotropis gigantea fiber and light impurities enter the first filtering bin 14 from the first air outlet hole 10, the fiber collecting pipe 11 and the second air inlet hole 13 in sequence under the drive of airflow; the light impurities with different sizes are intercepted by the first mesh plate 15 and the second mesh plate 17 in sequence, and the calotropis gigantea fiber is finally collected in the collection bin 18; after the calotropis gigantea fiber extraction is completed, the pure calotropis gigantea fiber in the collection bin 18 is collected, and the calotropis gigantea impurities in the first filtration bin 14, the second filtration bin 16 and the microwave box 2 are cleaned, so that the operation is simple and the use is convenient.

In an alternative embodiment, an explosion-proof mesh enclosure 4 is included; the anti-explosion mesh enclosure 4 is arranged in the microwave box 2, the end face, facing the bottom surface of the microwave box 2, of the anti-explosion mesh enclosure 4 is tightly pressed with the bottom surface of the microwave box 2, and an anti-explosion bin for accommodating the rotary tray 5 and the rotating shaft 6 is formed by the inner wall of the anti-explosion mesh enclosure 4 and the bottom surface of the microwave box 2;

a small amount of ox horn melon shells and bag pieces that the explosion-proof screen panel 4 that is equipped with produced after blasting the ox horn melon fiber raw materials intercept and drop to the bottom surface in explosion-proof storehouse to the area that scatters of shrink ox horn melon shells and bag pieces, conveniently cleans it.

In an alternative embodiment, a connecting tube 20 is included; the pipe orifice of one end of the connecting pipe 20 is connected with the air inlet end of the air suction device 21, and the pipe orifice of the other end of the connecting pipe 20 is connected with the second air outlet hole 19.

In an alternative embodiment, two microwave generators 9 are provided; the two microwave generators 9 are distributed at the top of the microwave box 2 side by side, wherein the microwave generators 9 are arranged symmetrically by taking the central axis of the first air outlet 10 as the center.

In an alternative embodiment, a movable plate 22 is included; the movable plate 22 is provided with a first groove and a second groove in parallel; wherein, an opening is arranged on any end face of the composite fiber collecting box 12 perpendicular to the first mesh plate 15;

the movable plate 22 presses the end surface of the composite fiber collecting box 12 towards the end surface of the opening of the composite fiber collecting box 12; the first mesh plate 15 is inserted into the first groove in a matching manner, and the end face, positioned in the first groove, of the first mesh plate 15 compresses the inner wall of the first groove; the second mesh plate 17 is inserted into the second groove in a matching manner, and the end face of the second mesh plate 17 positioned in the first groove compresses the inner wall of the second groove.

The utility model discloses still provide a use method about calotropis gigantea fibre extraction element, including following specific step:

s1, spreading the calotropis gigantea fiber raw material to be extracted on a rotating tray 5 in a microwave box 2;

s2, the driving device 7 is electrified to operate to drive the rotating tray 5 to rotate;

s3, the microwave generator 9 is electrified to operate to perform microwave blasting on the calotropis gigantea fiber raw material to obtain calotropis gigantea fibers, calotropis gigantea shells and calotropis gigantea capsule fragments;

s4, after the mudar floss raw material is blasted, the sound control sensor 8 receives the blasting sound and sends the received signal to the controller, and the controller controls the air blowing device 1 and the air suction device 21 to be electrified and operated;

the blowing device 1 blows air into the microwave box 2 from the first air inlet, and the mudar fibers and the light impurities float in the microwave box 2;

the air suction device 21 pumps out the air in the microwave box 2 and the composite fiber collecting box 12 so that the insides of the microwave box 2 and the composite fiber collecting box 12 are both in negative pressure;

s5, the mudar floss and the light impurities are driven by the airflow to enter the first filtering bin 14 through the first air outlet hole 10, the fiber collecting pipe 11 and the second air inlet hole 13 in sequence;

the light impurities with different sizes are intercepted by the first mesh plate 15 and the second mesh plate 17 in sequence, and the calotropis gigantea fiber is finally collected in the collection bin 18;

s6, closing the blowing device 1, the driving device 7, the microwave generator 9 and the air suction device 21;

pure calotropis gigantea fibers in the collection bin 18 are collected, and impurities of the calotropis gigantea in the first filter bin 14, the second filter bin 16 and the microwave box 2 are cleaned.

In an alternative embodiment, the operation power of the microwave generator 9 in S3 is 500-900W, the frequency is 6000MHz, and the operation time is 5-10 min.

In an alternative embodiment, the speed of the wind blown into the microwave box in S4 is 0.1-0.5 m/S.

In an optional embodiment, the vacuum degree inside the microwave box 2 and the composite fiber collecting box 12 in the step S4 is-300-700 mmHg; the air suction speed of the air suction device 21 in S4 is 0.1-6.0 m³/s。

According to the utility model provides a calotropis gigantea fibre extraction element and application method experiment, the experimental result sees table 1:

TABLE 1

The experimental results show that:

when calotropis gigantea fiber raw materials with the same quality are extracted under the same microwave power, the impurity content of the obtained calotropis gigantea fiber tends to decrease firstly and then increase along with the increase of the frequency of the calotropis gigantea fiber raw materials;

under the experimental condition that the frequency of the microwave generator is set to be 6000MHz, the extracted mudar fiber is the purest, and the impurity content is less than 0.5%;

the impurity content of the extracted mudar floss is 2.8% under the experimental condition that the frequency of the microwave generator is set to 8000 MHz; the broken capsules on the mudar floss enable the impurity content of the mudar floss to be improved, which is probably because the capsules have the characteristic of frangibility, the frequency of a microwave generator is too high, the movement of internal molecules is too fast, and the stored internal energy is too much, so that the capsules are broken;

secondly, when the calotropis gigantea fiber raw materials with the same quality are extracted under the same microwave frequency:

when the power is 700W, the extracted calotropis gigantea fiber is purest, and the impurity content of the calotropis gigantea fiber is less than 0.5%;

when the power is 500W, the impurity content of the extracted calotropis gigantea fibers is 5.6 percent, which is caused by insufficient blasting;

when the power is 900W, the impurity content of the extracted calotropis gigantea fibers is less than 0.5%, but a small amount of damage exists on microscopic fiber macromolecular chains in the obtained calotropis gigantea fibers, which is probably due to fiber damage caused by overlarge heating power;

from the above results, the fiber impurity content of the extracted fibers of the guava fruits with the weight of 5kg and 3kg is 0.5%, however, more fibers of the guava fruits with the weight of 5kg can be extracted, and the resources are effectively utilized, so that more fibers of the guava fruits can be extracted by performing microwave explosion on the guava fruits under the conditions of the same extraction time and the microwave power of 700W and the microwave frequency of 6000MHz, and the resources are effectively utilized, thereby saving the energy.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundaries of the appended claims or the equivalents of such scope and boundaries.

Claims (5)

1. The extraction device for the mudar floss is characterized by comprising a blowing device (1), a microwave box (2), a rotary tray (5), a driving device (7), a sound control inductor (8), a fiber collecting pipe (11), a combined fiber collecting box (12), an air suction device (21) and a controller;

a first air inlet hole (3) and a first air outlet hole (10) are formed in the microwave box (2); a microwave generator (9) is arranged in the microwave box (2), and a rotating shaft (6) is rotatably arranged on the bottom surface in the microwave box (2); wherein, the first air inlet hole (3) is connected with the air outlet end of the blowing device (1); the rotating shaft (6) is in transmission connection with the driving device (7), the rotating shaft (6) is perpendicular to the bottom surface of the microwave box (2), and the end surface, far away from the microwave box (2), of the rotating shaft (6) is connected with the rotating tray (5);

the composite fiber collecting box (12) and the microwave box (2) are arranged side by side, and a first mesh plate (15) and a second mesh plate (17) are arranged in the composite fiber collecting box (12); the first mesh plate (15) and the second mesh plate (17) are distributed side by side and used for sequentially dividing the interior of the composite fiber collecting box (12) into a first filtering bin (14), a second filtering bin (16) and a collecting bin (18), and first filtering holes (151) used for communicating the first filtering bin (14) with the second filtering bin (16) are uniformly formed in the first mesh plate (15); second filtering holes (171) for communicating the second filtering bin (16) and the collecting bin (18) are uniformly formed in the second mesh plate (17); wherein the diameter of each second filtering hole (171) is not larger than that of each first filtering hole (151);

the first filter bin (14) is provided with a second air inlet hole (13) on the composite fiber collecting box (12); wherein, the second air inlet hole (13) is connected with a pipe orifice at one end of the fiber collecting pipe (11); the other end pipe orifice of the fiber collecting pipe (11) is connected with the first air outlet hole (10);

the collection bin (18) is provided with a second air outlet hole (19) on the composite fiber collection box (12); wherein, the second air outlet (19) is connected with the air inlet end of the air suction device (21);

the signal output end of the sound control inductor (8) is connected with the signal output end of the controller; a plurality of signal output ends of the controller are respectively connected with the signal input end of the blowing device (1) and the signal input end of the air suction device (21).

2. The apparatus for extracting the fiber of the chaulmoogra according to claim 1, comprising an explosion-proof mesh enclosure (4); the anti-explosion net cover (4) is arranged in the microwave box (2), the end face, facing the bottom face of the microwave box (2), of the anti-explosion net cover (4) is tightly pressed with the bottom face of the microwave box (2), and an anti-explosion bin used for containing the rotary tray (5) and the rotating shaft (6) is formed by the inner wall of the anti-explosion net cover (4) and the bottom face of the microwave box (2).

3. A chaulmoogra fiber extraction device as claimed in claim 1, comprising a connecting tube (20); the pipe orifice of one end of the connecting pipe (20) is connected with the air inlet end of the air suction device (21), and the pipe orifice of the other end of the connecting pipe (20) is connected with the second air outlet hole (19).

4. The apparatus for extracting the fiber of the cantaloupe according to claim 1, wherein two microwave generators (9) are provided; the two microwave generators (9) are distributed at the top of the microwave box (2) side by side, wherein the microwave generators (9) are symmetrically arranged by taking the central axis of the first air outlet hole (10) as the center.

5. The apparatus for extracting chaulmoogra fiber as claimed in claim 1, comprising a movable plate (22); the movable plate (22) is provided with a first groove and a second groove in parallel; wherein, an opening is arranged on any end face of the composite fiber collecting box (12) perpendicular to the first mesh plate (15);

the movable plate (22) presses the end surface of the composite fiber collecting box (12) towards the end surface of the opening of the composite fiber collecting box (12); the first mesh plate (15) is inserted into the first groove in a matching manner, and the end face, positioned in the first groove, of the first mesh plate (15) compresses the inner wall of the first groove; the second mesh plate (17) is inserted into the second groove in a matching mode, and the end face, located in the first groove, of the second mesh plate (17) compresses the inner wall of the second groove.

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