CN114682110B - Emulsifying device for textile auxiliary processing - Google Patents

Abstract

The invention discloses an emulsifying device for textile auxiliary processing, and relates to the technical field of chemical reagent emulsification. The invention comprises an emulsifying box, a material conveying box and a material conveying box, wherein a flow limiting plate is arranged in the material conveying box, and material injection holes and air injection pipes are arranged on the surface of the material conveying box and are alternately distributed; a pressing pipe is arranged above the feeding box. According to the invention, through arranging the material conveying box, the material feeding box and the material pressing pipe, the material liquid can form a more stable oil-in-water state by quantitatively and limitedly injecting the target material liquid into water, so that the emulsification success rate is improved; wherein, through setting up the current limiting plate in the delivery box, utilize the notes material hole and the gas injection pipe of arranging in turn, at the notes material in-process, accomplish and fill material back promptly inwards after the material is once annotated, utilize the atmospheric pressure effect to go into in the water with the material hydraulic pressure in the notes material pipe, simultaneously because the isolated of air, the emulsion oil drop that the liquid drop of successively injecting into forms is also isolated each other, can prevent mutual adhesion, avoids the mutual influence to destroy steady state.

Description

Emulsifying device for textile auxiliary processing

Technical Field

The invention belongs to the technical field of chemical reagent emulsification, and particularly relates to an emulsifying device for textile auxiliary processing.

Background

Textile auxiliary is not a single chemical reagent generally, mainly refers to chemicals necessary in the textile production and processing process, wherein about 80% of the product components are prepared from surfactant as raw materials, and the rest 20% are functional auxiliary; due to the special purpose of the textile auxiliary, when the textile auxiliary is added in textile processing, part of the textile auxiliary needs to be emulsified so as to achieve the ideal production effect;

the existing emulsifying equipment generally needs to control conditions such as the emulsifying working environment and the like according to different physicochemical properties of materials, and the actual operation process is complex; the textile auxiliary has various types and relatively variable physicochemical properties, so that the operation burden of staff is definitely increased in the process of repeatedly controlling the emulsification conditions; meanwhile, the basic operation of the traditional emulsifying equipment is simple stirring, and the emulsifying efficiency is not high; in order to solve the problems, an emulsifying device for processing textile auxiliary is designed.

Disclosure of Invention

The invention aims to provide an emulsifying device for textile auxiliary processing, which solves the problems of lack of convenience and low emulsifying efficiency when the existing emulsifying equipment is used for controlling the emulsifying reaction conditions or environment.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention relates to an emulsifying device for textile auxiliary processing, which comprises an emulsifying box, a terminal console, a feeding box and a supporting connecting frame, wherein the terminal console and the emulsifying box are connected into an integrated structure, and one side surface of the terminal console is welded and fixed with the supporting connecting frame; one side surface of the emulsifying box is fixedly bolted with the feeding box;

a material conveying box is fixedly bolted to one side surface of the emulsifying box, is positioned below the material conveying box and is communicated with the material conveying box; a plurality of material injection pipes are arranged on one side surface of the material conveying box and are communicated to the inside of the emulsifying box in an extending manner; the inner surface of the material conveying box is slidably clamped with a current limiting plate, and the surface of the current limiting plate is provided with a material injection hole and is communicated with a material injection pipe through the material injection hole; an air injection pipe is arranged between two adjacent material injection holes, and a plurality of air injection pipes are connected in parallel and then extend to the outside of the material conveying box and are in sliding fit with the material conveying box;

the material injection holes and the gas injection pipes are arranged in a staggered manner, when the current limiting plate slides back and forth, the material is alternately injected or inflated into the emulsification box sequentially through the current limiting plate and the gas injection pipes, after the material is injected once, the current limiting plate slides to enable the gas injection pipes to be communicated with the gas injection pipes, pressurized air is injected inwards, and the injected material liquid is pressed into the emulsification box by utilizing aerodynamic force;

the upper surface of the feeding box is connected with a pressing pipe in a bolting way, and a pressing plug is slidably arranged in the pressing pipe; a material pressing wire shaft is welded on one surface of the material pressing plug, and extends to the outside of the material pressing pipe; the pressing sleeve is rotationally sleeved at one end of the pressing pipe and only serves as a driving connecting piece for driving the pressing wire shaft to slide, so that the pressing sleeve is rotationally matched with one end of the pressing pipe and is meshed with the pressing wire shaft to form a reciprocating screw rod structure;

the outer surface of the material conveying box is bolted with a material conveying motor, the peripheral side surface of an output shaft of the material conveying motor is provided with threads, and the other end of the output shaft of the material conveying motor is connected with a rotary shaft of the supporting connecting frame; one end of the current limiting plate is adhered with a wire plate, and the wire plate and an output shaft of the feeding motor form a reciprocating screw structure; the output shaft of the feeding motor is linked with the pushing sleeve through a transmission belt;

in the structure, when the feeding motor is started, the output shaft drives the flow limiting plate to slide back and forth, and the material is injected and inflated into the emulsification box alternately; meanwhile, the pushing sleeve is driven to rotate, and the screw rod structure is utilized to enable the material pressing plug to apply pressure to the material liquid in the feeding box and the material conveying box, so that material injection is facilitated.

Further, the limiting plate is welded at one end of the material pressing wire shaft, the limiting sliding groove is formed in one side face of the supporting connecting frame, one side face of the limiting plate extends to the inside of the limiting sliding groove and is in sliding clamping with the limiting plate, and the sliding track of the material pressing wire shaft can be limited, so that material pressing is stable.

Further, an air inlet pipe is welded and communicated with one side surface of the material pressing pipe, a one-way valve is arranged in the air inlet pipe, a sealing structure is arranged between the material injection pipe and the emulsifying box, and the one-way valve is arranged on the inner surface of the material injection pipe; when one material pressing cycle is completed, the material pressing wire shaft reversely slides and resets under the continuous rotation of the pushing sleeve, and the air inlet pipe can inject air into the material pressing pipe to participate in the next material pressing cycle; the check valve in the material injection pipe can prevent liquid in the emulsifying box from being reversely pressed into the material conveying box.

Further, the terminal console is of an L-shaped frame structure, an adjusting shaft is arranged on one end face of the terminal console, a stirring motor is sleeved on the peripheral side face of the adjusting shaft, and one end of an output shaft of the stirring motor is meshed and sleeved with the stirring shaft; the stirring shaft extends to the inside of the emulsification box and is in rotary fit with the emulsification box through a bearing.

Further, the upper surface and the lower surface of the emulsification box are respectively welded and communicated with a water injection pipe and a discharge pipe, wherein the water injection pipe and the discharge pipe extend to the outside of the emulsification box.

Further, an adjusting chute is formed in one surface of the terminal console, and one side surface of the stirring motor extends into the adjusting chute and is in sliding clamping connection with the adjusting chute; the air injection pipe is a flexible pipe, and the outer end of the air injection pipe is connected with the pressurizing air pump; the material pressing plug and the material pressing pipe form a piston structure.

The invention has the following beneficial effects:

according to the invention, through arranging the material conveying box, the material feeding box and the material pressing pipe, the material liquid can form a more stable oil-in-water state by quantitatively and limitedly injecting the target material liquid into water, so that the emulsification success rate is improved; wherein, by arranging the flow limiting plate in the material conveying box, the material in the material conveying pipe is hydraulically filled into water by utilizing the air pressure effect by utilizing the material filling holes and the air filling pipes which are alternately arranged after the material is filled once in the material filling process, meanwhile, due to the isolation of air, emulsion oil drops formed by liquid drops of feed liquid injected in sequence are isolated from each other, so that mutual adhesion can be prevented, and the stable state is prevented from being damaged due to mutual influence; through making the swage silk axle in the swage pipe and current limiting plate synchronous motion, can make the process of emulsification more stable, further improve emulsification efficiency.

Of course, it is not necessary for any one product to practice the invention to achieve all of the advantages set forth above at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed for 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 that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is an assembled block diagram of an emulsifying device for processing textile auxiliaries according to the present invention;

FIG. 2 is a partial, pictorial illustration of portion A of FIG. 1;

FIG. 3 is a top view of an emulsifying device for processing textile auxiliary according to the present invention;

FIG. 4 is a schematic view of the structure of section B-B in FIG. 3;

FIG. 5 is a partial, displayed view of portion D of FIG. 4;

FIG. 6 is a schematic view of the structure of section E-E in FIG. 4;

FIG. 7 is a schematic view of the structure of section C-C in FIG. 3;

FIG. 8 is a partial view showing portion H of FIG. 7;

FIG. 9 is a schematic view of the structure of section F-F in FIG. 4;

fig. 10 is a partially-shown view of the portion G in fig. 9.

In the drawings, the list of components represented by the various numbers is as follows:

1. an emulsifying box; 2. a terminal console; 3. a feeding box; 4. a support connection frame; 5. a material conveying box; 501. a material injection pipe; 502. a flow-limiting plate; 503. a material injection hole; 504. an air injection pipe; 6. pressing a material pipe; 602. a material pressing wire shaft; 603. pushing and pressing the sleeve; 505. a feeding motor; 506. a silk plate; 604. a limiting plate; 401. limiting sliding grooves; 605. an air inlet pipe; 201. an adjusting shaft; 202. a stirring motor; 203. a stirring shaft; 101. a water injection pipe; 102. and a discharge pipe.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be understood that the terms "upper," "middle," "outer," "inner," and the like indicate an orientation or a positional relationship, and are merely for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the components or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Example 1:

referring to fig. 1-10, the invention discloses an emulsifying device for processing textile auxiliary, which comprises an emulsifying box 1, a terminal console 2, a feeding box 3 and a supporting connecting frame 4, wherein the terminal console 2 and the emulsifying box 1 are connected into an integral structure, and one side surface of the terminal console 2 is welded and fixed with the supporting connecting frame 4; one side surface of the emulsifying box 1 is fixedly bolted with the feeding box 3;

one side surface of the emulsifying box 1 is also fixedly connected with a material conveying box 5 in a bolting way, and the material conveying box 5 is positioned below the material conveying box 3 and is communicated with the material conveying box 3; a plurality of injection pipes 501 are arranged on one side surface of the material conveying box 5, and the injection pipes 501 are communicated to the inside of the emulsifying box 1 in an extending way; the inner surface of the material conveying box 5 is slidably clamped with a current limiting plate 502, and the surface of the current limiting plate 502 is provided with a material injection hole 503 and is communicated with a material injection pipe 501 through the material injection hole 503; an air injection pipe 504 is arranged between two adjacent material injection holes 503, and a plurality of air injection pipes 504 are connected in parallel and then extend to the outside of the material conveying box 5, and are in sliding fit with the material conveying box 5;

wherein the material injection holes 503 and the gas injection pipes 504 are staggered, when the current limiting plate 502 slides reciprocally, material is alternately injected or inflated into the emulsification box 1 sequentially through the current limiting plate 502 and the material injection pipes 501, after material injection is performed once, the current limiting plate 502 slides to enable the gas injection pipes 504 to be communicated with the material injection pipes 501, pressurized air is injected inwards, and the injected material liquid is pressed into the emulsification box 1 by utilizing aerodynamic force;

the upper surface of the feeding box 3 is connected with a pressing pipe 6 in a bolting way, and a pressing plug is slidably arranged in the pressing pipe 6; a material pressing wire shaft 602 is welded on one surface of the material pressing plug, and the material pressing wire shaft 602 extends to the outside of the material pressing pipe 6; one end of the pressing pipe 6 is rotatably sleeved with a pressing sleeve 603, wherein the pressing sleeve 603 is only used as a driving connecting piece for driving the pressing wire shaft 602 to slide, so that the pressing sleeve 603 is rotatably matched with one end of the pressing pipe 6 on one hand and is meshed with the pressing wire shaft 602 to form a reciprocating screw structure;

the outer surface of the material conveying box 5 is bolted with a material conveying motor 505, the peripheral side surface of an output shaft of the material conveying motor 505 is provided with threads, and the other end of the output shaft is connected with a rotary shaft of the supporting connecting frame 4; one end of the flow limiting plate 502 is adhered with a wire plate 506, and the wire plate 506 and an output shaft of the feeding motor 505 form a reciprocating screw structure; the output shaft of the feeding motor 505 is linked with the pushing sleeve 603 through a transmission belt;

in the above structure, when the feeding motor 505 is started, the output shaft drives the flow limiting plate 502 to slide reciprocally, and material is injected and inflated into the emulsification box 1 alternately; simultaneously, the pushing sleeve 603 is driven to rotate, and the feed liquid in the feeding box 3 and the feed box 5 is pressurized by the material pressing plug through the screw rod structure, so that the feeding is facilitated.

Example 2:

one end of the material pressing wire shaft 602 is welded with a limiting plate 604, a limiting chute 401 is formed in one side face of the supporting connecting frame 4, and one side face of the limiting plate 604 extends into the limiting chute 401 and is in sliding clamping with the limiting chute 401, so that the sliding track of the material pressing wire shaft 602 can be limited, and the material pressing is more stable.

Preferably, an air inlet pipe 605 is welded and communicated with one side surface of the pressing pipe 6, a one-way valve is arranged in the air inlet pipe 605, a sealing structure is arranged between the injection pipe 501 and the emulsifying box 1, and the one-way valve is arranged on the inner surface of the injection pipe 501; when one pressing cycle is completed, under the continuous rotation of the pressing sleeve 603, the pressing wire shaft 602 slides reversely and resets, and the air inlet pipe 605 can inject air into the pressing pipe 6 to participate in the next pressing cycle; the one-way valve in the filling pipe 501 prevents the liquid in the emulsifying tank 1 from being pressed back into the interior of the feed box 5.

Example 3:

the terminal console 2 is of an L-shaped frame structure, an adjusting shaft 201 is arranged on one end face of the terminal console, a stirring motor 202 is sleeved on the peripheral side face of the adjusting shaft 201, and a stirring shaft 203 is sleeved on one end of an output shaft of the stirring motor 202 in a meshed manner; the stirring shaft 203 extends to the inside of the emulsification tank 1 and is rotatably fitted with the emulsification tank 1 through a bearing.

Preferably, the upper surface and the lower surface of the emulsion tank 1 are respectively welded and communicated with a water injection pipe 101 and a discharge pipe 102, wherein the water injection pipe 101 and the discharge pipe 102 extend to the outside of the emulsion tank 1.

Preferably, an adjusting chute is formed on one surface of the terminal console 2, and one side surface of the stirring motor 202 extends into the adjusting chute and is in sliding engagement with the adjusting chute; the gas injection pipe 504 is a flexible pipe, and the outer end of the gas injection pipe is connected with a pressurizing gas pump; the plunger and the pressing pipe 6 form a piston structure.

It should be added that, in the invention, an adjusting motor for adjusting the height of the stirring motor 202 can be further arranged inside the terminal console 2, so that the stirring motor 202 can be started by utilizing an electromechanical structure;

the invention mainly uses a pressurizing material injection mode to quantitatively and limitedly press textile auxiliary into water to realize the most stable oil-in-water state in emulsion, and the emulsification process in the mode does not need to consider the surface tension of water, the temperature and the change of flow velocity of two phases, thus the operation process and the emulsification process are simpler than the traditional emulsification process; and the structure such as the stirring shaft 203 is added on the emulsifying box 1, so that the precise control on the emulsifying process can be realized under different conditions, and the emulsifying efficiency is further improved.

In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended only to assist in the explanation of the invention. The preferred embodiments are not exhaustive or to limit the invention to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best understand and utilize the invention. The invention is limited only by the claims and the full scope and equivalents thereof.

Claims (2)

1. The utility model provides an emulsification device is used in textile auxiliary processing, includes emulsion case (1), terminal control cabinet (2), pay-off box (3) and support link (4), its characterized in that: the terminal control console (2) and the emulsifying box (1) are connected into an integral structure, and one side surface of the terminal control console (2) is welded and fixed with the supporting connecting frame (4); one side surface of the emulsifying box (1) is fixedly bolted with the feeding box (3);

one side surface of the emulsifying box (1) is also bolted and fixed with a material conveying box (5), and the material conveying box (5) is positioned below the material conveying box (3) and is communicated with the material conveying box; a plurality of material injection pipes (501) are arranged on one side surface of the material conveying box (5), and the material injection pipes (501) are communicated to the inside of the emulsifying box (1) in an extending way; the inner surface of the material conveying box (5) is slidably clamped with a current limiting plate (502), and a material injection hole (503) is formed in the surface of the current limiting plate (502) and is communicated with the material injection pipe (501) through the material injection hole (503); an air injection pipe (504) is arranged between two adjacent material injection holes (503), and a plurality of air injection pipes (504) are connected in parallel and then extend to be communicated to the outside of the material conveying box (5) and are in sliding fit with the material conveying box (5);

the upper surface of the feeding box (3) is connected with a pressing pipe (6) in a bolting way, and a pressing plug is slidably arranged in the pressing pipe (6); a material pressing wire shaft (602) is welded on one surface of the material pressing plug, and the material pressing wire shaft (602) extends to the outside of the material pressing pipe (6); one end of the pressing pipe (6) is rotatably sleeved with a pressing sleeve (603), and a reciprocating screw rod structure is formed between the pressing sleeve (603) and the pressing wire shaft (602);

the outer surface of the material conveying box (5) is bolted with a material conveying motor (505), the peripheral side surface of an output shaft of the material conveying motor (505) is provided with threads, and the other end of the output shaft is connected with a rotary shaft of the supporting connecting frame (4); one end of the current limiting plate (502) is adhered with a wire plate (506), and the wire plate (506) and an output shaft of the feeding motor (505) form a reciprocating screw structure; the output shaft of the feeding motor (505) is linked with the pushing sleeve (603) through a transmission belt;

a limiting plate (604) is welded at one end of the material pressing wire shaft (602), a limiting chute (401) is formed in one side surface of the supporting connecting frame (4), and one side surface of the limiting plate (604) extends into the limiting chute (401) and is in sliding clamping connection with the limiting chute;

an air inlet pipe (605) is welded and communicated with one side surface of the pressing pipe (6), and a one-way valve is arranged in the air inlet pipe (605);

a sealing structure is arranged between the material injection pipe (501) and the emulsifying box (1), and a one-way valve is arranged on the inner surface of the material injection pipe (501);

the terminal console (2) is of an L-shaped frame structure, an adjusting shaft (201) is installed on one end face of the terminal console, a stirring motor (202) is sleeved on the peripheral side face of the adjusting shaft (201), and a stirring shaft (203) is sleeved at one end of an output shaft of the stirring motor (202) in a meshed mode; the stirring shaft (203) extends into the emulsifying box (1) and is in rotary fit with the emulsifying box (1) through a bearing;

the upper surface and the lower surface of the emulsification box (1) are respectively welded and communicated with a water injection pipe (101) and a discharge pipe (102), wherein the water injection pipe (101) and the discharge pipe (102) are both extended to the outside of the emulsification box (1).

2. The emulsifying device for processing textile auxiliary according to claim 1, wherein an adjusting chute is formed on one surface of the terminal console (2), and one side surface of the stirring motor (202) extends into the adjusting chute and is in sliding engagement with the adjusting chute; the gas injection pipe (504) is a flexible pipe, and the outer end of the gas injection pipe is connected with the pressurizing gas pump; the material pressing plug and the material pressing pipe (6) form a piston structure.