CN210420496U

CN210420496U - Energy-saving raw material dewatering device for short fiber production

Info

Publication number: CN210420496U
Application number: CN201920601566.8U
Authority: CN
Inventors: 王杰
Original assignee: Haining Honggao Chemical Fiber Co ltd
Current assignee: Zhejiang Hong Hi Tech Materials Technology Co ltd
Priority date: 2019-04-29
Filing date: 2019-04-29
Publication date: 2020-04-28
Anticipated expiration: 2029-04-29

Abstract

The utility model discloses a raw materials dewatering device is used in production of energy-saving short-staple, including dehydration chamber, singlechip, backup pad and porous stainless steel jar, the universal wheel is all installed to four corners of backup pad bottom, one side on backup pad top is provided with the steam treatment chamber, control panel is all installed on the top of steam treatment chamber one side, and control panel's internally mounted has the singlechip, the top in steam treatment chamber is connected with the three-way pipe, the stabilizer blade is all installed to the both sides of steam treatment chamber bottom, the fan is installed on the inside top in steam treatment chamber, the dehydration chamber is installed to the opposite side on backup pad top. The utility model discloses an install solar cell panel, solar cell panel installs on the top of lid, and under the sufficient condition of sunshine, solar cell panel accessible photovoltaic controller turns into the electric energy with light energy, stores the electric energy in the inside of battery, supplies this device to use, makes the device energy-concerving and environment-protective more.

Description

Energy-saving raw material dewatering device for short fiber production

Technical Field

The utility model relates to a dewatering equipment technical field specifically is an energy-saving raw materials dewatering device for short-staple production.

Background

Short fibers are subjected to troubles such as rotting and worm erosion in the storage process, so that dehydration treatment is needed to prolong the storage time of the short fibers, but the conventional raw material dehydration device for short fiber production has many problems or defects:

firstly, the traditional raw material dehydration device for short fiber production cannot dehydrate thoroughly, so that the short fibers are easy to suffer from wormhole, rot and the like in the storage process;

secondly, the traditional raw material dehydration device for short fiber production completely adopts an external power supply, does not well utilize solar energy, and is not energy-saving and environment-friendly;

thirdly, the traditional raw material dehydration device for short fiber production does not treat water dehydrated by short fibers, thereby causing resource waste.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an energy-saving short-staple production is with raw materials dewatering device to solve the dehydration that proposes in the above-mentioned background art thoroughly, not energy-concerving and environment-protective and the extravagant problem of resource.

In order to achieve the above object, the utility model provides a following technical scheme: an energy-saving raw material dehydration device for short fiber production comprises a dehydration cavity, a single chip microcomputer, a support plate and a porous stainless steel tank, universal wheels are mounted at four corners of the bottom end of the support plate, a steam treatment cavity is arranged at one side of the top end of the support plate, a control panel is mounted at the top end of one side of the steam treatment cavity, the single chip microcomputer is mounted in the control panel, a three-way pipe is connected to the top end of the steam treatment cavity, support legs are mounted at two sides of the bottom end of the steam treatment cavity, a fan is mounted at the top end of the inside of the steam treatment cavity, the dehydration cavity is mounted at the other side of the top end of the support plate, the other two ends of the three-way pipe are communicated with two sides of the top end of the dehydration cavity, a cover body is mounted at the top end of the dehydration cavity, a storage battery is mounted at the, PTC heating element is all installed to the both sides of dehydration intracavity portion, second servo motor is installed on the top of dehydration intracavity portion, and porous stainless steel jar is installed on the top of second servo motor, the outside of porous stainless steel jar is evenly fixed with spacing retainer plate, first servo motor is installed on the top of porous stainless steel jar, and first servo motor's bottom installs the (mixing) shaft, control panel and humidity transducer's output are respectively through the input electric connection of wire with the singlechip, the output of singlechip is respectively through wire and fan, first servo motor and second servo motor's input electric connection.

Preferably, temperature sensors are mounted on two sides of the bottom end of the inner part of the dewatering cavity, and the temperature sensors are symmetrically distributed around the vertical center line of the dewatering cavity.

Preferably, the condenser pipe is installed to the bottom of fan, the bottom of condenser pipe is provided with the water catch bowl, the condenser pipe is "snake" type.

Preferably, the draw-in groove is all installed to the both sides of the inside bottom in steam treatment chamber, and all is provided with the filtration sieve between draw-in groove and the draw-in groove, and the fixture block is all installed to the both sides of filtering the sieve, constitutes the block structure between fixture block and the draw-in groove.

Preferably, the filter sieve plates are arranged in the steam treatment cavity at equal intervals.

Preferably, a cover is installed at the top end of the porous stainless steel tank, and the first servo motor is installed at the bottom end of the cover.

Compared with the prior art, the beneficial effects of the utility model are that: this kind of energy-saving short-staple production is with raw materials dewatering device rational in infrastructure, has following advantage:

1. the first servo motor is arranged at the top end inside the porous stainless steel tank, the first servo motor drives the stirring shaft to rotate, short fibers inside the porous stainless steel tank are stirred, the contact abrasion area of the short fibers and hot air is increased, meanwhile, the second servo motor drives the porous stainless steel tank to rotate, so that the short fibers and the hot air are contacted more uniformly, the dehydration effect is more thorough and faster, and the worm erosion and the corrosion of the short fibers in the storage process are avoided;

2. the solar panel is arranged at the top end of the cover body, so that under the condition of sufficient sunlight, the solar panel can convert light energy into electric energy through the photovoltaic controller, and the electric energy is stored in the storage battery and used by the device, so that the device is more energy-saving and environment-friendly;

3. through installing the fan, the fan is installed on the inside top of steam treatment chamber, takes out the inside of steam treatment chamber through the three-way pipe with the inside steam in dehydration chamber, and the condenser pipe is with the vapor condensation, collects through the water catch bowl, and rethread filters the sieve and filters steam, makes water reach the state that can supply reuse, avoids the waste of resource.

Drawings

Fig. 1 is a schematic front view of a cross-sectional structure of the present invention;

FIG. 2 is a left side view schematic structural diagram of the porous stainless steel tank of the present invention;

fig. 3 is a schematic view of the structure of the condenser tube of the present invention;

fig. 4 is a system block diagram of the present invention.

In the figure: 1. a storage battery; 2. a cover body; 3. a dehydration cavity; 4. a three-way pipe; 5. a fan; 6. a steam treatment chamber; 7. a single chip microcomputer; 8. a control panel; 9. a condenser tube; 10. a water collecting hopper; 11. filtering the sieve plate; 12. a clamping block; 13. a card slot; 14. a support leg; 15. a support plate; 16. a solar panel; 17. a humidity sensor; 18. a first servo motor; 19. a stirring shaft; 20. a porous stainless steel can; 21. a PTC heating element; 22. a second servo motor; 23. a temperature sensor; 24. a universal wheel; 25. and a limiting fixing ring.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, 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 work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides an embodiment: an energy-saving raw material dehydration device for short fiber production comprises a dehydration cavity 3, a single chip microcomputer 7, a support plate 15 and a porous stainless steel tank 20, wherein universal wheels 24 are respectively arranged at four corners of the bottom end of the support plate 15, a steam treatment cavity 6 is arranged at one side of the top end of the support plate 15, a control panel 8 is respectively arranged at the top end of one side of the steam treatment cavity 6, a single-chip microcomputer 7 is installed inside the control panel 8, the type of the single-chip microcomputer 7 can be HT66F018, the top end of the steam treatment cavity 6 is connected with a three-way pipe 4, support legs 14 are installed on two sides of the bottom end of the steam treatment cavity 6, a fan 5 is installed on the top end inside the steam treatment cavity 6, the type of the fan 5 can be COSAN49, a condensation pipe 9 is installed at the bottom end of the fan 5, a water collecting hopper 10 is arranged at the bottom end of the condensation pipe 9, the condensation pipe 9 is snake-shaped, the contact surface of the condensation pipe 9 and water vapor is increased, and the condensation effect is better;

the filtering sieve plates 11 are arranged in the steam treatment cavity 6 at equal intervals, so that the filtering effect is more thorough;

clamping grooves 13 are respectively arranged on two sides of the bottom end in the steam treatment cavity 6, a filtering sieve plate 11 is arranged between each clamping groove 13 and each clamping groove 13, clamping blocks 12 are respectively arranged on two sides of each filtering sieve plate 11, and a clamping structure is formed between each clamping block 12 and each clamping groove 13, so that the disassembly and the assembly are convenient;

a dehydration cavity 3 is arranged on the other side of the top end of the support plate 15, the other two ends of the three-way pipe 4 are communicated with the two sides of the top end of the dehydration cavity 3, a cover body 2 is arranged on the top end of the dehydration cavity 3, a storage battery 1 is arranged on the top end of the cover body 2, a solar cell panel 16 is arranged on the top end of the storage battery 1, humidity sensors 17 are arranged on the two sides of the bottom end of the cover body 2, the type of the humidity sensors 17 can be DHT11, PTC heating elements 21 are arranged on the two sides of the interior of the dehydration cavity 3, the type of the PTC heating elements 21 can be MZFR-J, temperature sensors 23 are arranged on the two sides of the bottom end of the interior of the dehydration cavity 3, the type of the temperature sensors 23 can be CWDZ11, the temperature;

the top end in the dehydration cavity 3 is provided with a second servo motor 22, the type of the second servo motor 22 can be YE2, the top end of the second servo motor 22 is provided with a porous stainless steel tank 20, the outer side of the porous stainless steel tank 20 is uniformly fixed with a limiting fixing ring 25, the top end of the porous stainless steel tank 20 is provided with a first servo motor 18, the type of the first servo motor 18 can be 80DC, the bottom end of the first servo motor 18 is provided with a stirring shaft 19, the top end of the porous stainless steel tank 20 is provided with a cover, and the first servo motor 18 is arranged at the bottom end of the cover, so that the disassembly is convenient, and the cleaning of the stirring shaft 19 is convenient;

the output ends of the control panel 8, the temperature sensor 23 and the humidity sensor 17 are electrically connected with the input end of the single chip microcomputer 7 through leads respectively, and the output end of the single chip microcomputer 7 is electrically connected with the input ends of the fan 5, the first servo motor 18 and the second servo motor 22 through leads respectively.

The working principle is as follows: when the device is used, the cover body 2 is opened, the cover of the porous stainless steel tank 20 is opened at the same time, short fibers are placed inside the porous stainless steel tank 20, the cover and the cover body 2 are closed, the PTC heating element 21 starts to generate heat, the first servo motor 18 drives the stirring shaft 19 to stir the short fibers, the contact area between the short fibers and hot air is increased, the second servo motor 22 drives the porous stainless steel tank 20 to rotate, the short fibers inside the porous stainless steel tank 20 are in more uniform contact with the hot air, the short fibers are dehydrated more quickly and thoroughly, the humidity sensor 17 detects the humidity inside the dehydration cavity 3, the detected result is sent to the singlechip 7, the singlechip 7 processes data and then sends the data to the PTC heating element 21, the second servo motor 22 and the first servo motor 18, so that the temperature of the PTC heating element 21 and the drying time of the short fibers are controlled, fan 5 will dewater the inside of the vapor suction steam treatment chamber 6 that the chamber 3 inside dehydration produced, condense steam through condenser pipe 9, and the water after the condensation filters through filtering sieve 11, and the water after the filtration can be retrieved and recycled, avoids the waste of resource.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides an energy-saving short fiber production is with raw materials dewatering device, includes dehydration chamber (3), singlechip (7), backup pad (15) and porous stainless steel jar (20), its characterized in that: universal wheels (24) are mounted at four corners of the bottom of the supporting plate (15), a steam treatment cavity (6) is arranged at one side of the top of the supporting plate (15), a control panel (8) is mounted at the top of one side of the steam treatment cavity (6), a single chip microcomputer (7) is mounted inside the control panel (8), a three-way pipe (4) is connected to the top of the steam treatment cavity (6), support legs (14) are mounted on two sides of the bottom of the steam treatment cavity (6), a fan (5) is mounted at the top of the inside of the steam treatment cavity (6), a dewatering cavity (3) is mounted on the other side of the top of the supporting plate (15), the other two ends of the three-way pipe (4) are communicated with two sides of the top of the dewatering cavity (3), a cover body (2) is mounted at the top of the dewatering cavity (3), and a storage battery (1) is mounted at, solar cell panel (16) are installed on the top of battery (1), humidity transducer (17) are all installed to the both sides of lid (2) bottom, PTC heating element (21) are all installed to the inside both sides in dehydration chamber (3), second servo motor (22) are installed on the inside top in dehydration chamber (3), and porous stainless steel jar (20) are installed on the top of second servo motor (22), the outside of porous stainless steel jar (20) is evenly fixed with spacing retainer plate (25), first servo motor (18) are installed on the top of porous stainless steel jar (20), and (mixing) shaft (19) are installed to the bottom of first servo motor (18), the output of control panel (8) and humidity transducer (17) is respectively through the input electric connection of wire with singlechip (7), the output of singlechip (7) is respectively through wire and fan (5), The input ends of the first servo motor (18) and the second servo motor (22) are electrically connected.

2. The energy-saving raw material dewatering device for short fiber production according to claim 1, characterized in that: temperature sensors (23) are mounted on two sides of the bottom end inside the dewatering cavity (3), and the temperature sensors (23) are symmetrically distributed about the vertical center line of the dewatering cavity (3).

3. The energy-saving raw material dewatering device for short fiber production according to claim 1, characterized in that: condenser pipe (9) are installed to the bottom of fan (5), the bottom of condenser pipe (9) is provided with water catch bowl (10), condenser pipe (9) are "snake" type.

4. The energy-saving raw material dewatering device for short fiber production according to claim 1, characterized in that: draw-in groove (13) are all installed to the both sides of the inside bottom in steam treatment chamber (6), and all are provided with between draw-in groove (13) and filter sieve (11), and fixture block (12) are all installed to the both sides of filtering sieve (11), constitute the block structure between fixture block (12) and draw-in groove (13).

5. The energy-saving raw material dewatering device for short fiber production according to claim 4, characterized in that: the filtering sieve plates (11) are arranged in the steam treatment cavity (6) at equal intervals.

6. The energy-saving raw material dewatering device for short fiber production according to claim 1, characterized in that: a cover is installed at the top end of the porous stainless steel tank (20), and a first servo motor (18) is installed at the bottom end of the cover.