CN114381879A

CN114381879A - A spraying device for textile product production

Info

Publication number: CN114381879A
Application number: CN202111636161.6A
Authority: CN
Inventors: 陈坚
Original assignee: Dean County Sulilong Textile Co ltd
Current assignee: Dean County Sulilong Textile Co ltd
Priority date: 2021-12-29
Filing date: 2021-12-29
Publication date: 2022-04-22
Anticipated expiration: 2041-12-29
Also published as: CN114381879B

Abstract

The invention discloses a spraying device for textile product production, which comprises a nozzle, wherein the nozzle comprises a first cylinder body (1), a second cylinder body (2), an inner lining cylinder (3), a supporting cylinder (4) and a vortex body (5), and is characterized in that: the vortex generator comprises a support barrel, wherein a plurality of circulation holes (42) are formed in the support barrel, a guide hole is formed in the center of the support barrel, a connector (16) is connected to the outer peripheral side of the first barrel, a vortex atomization cavity is formed between the first barrel and the support barrel, a vortex body is arranged in the vortex atomization cavity, the vortex body (5) comprises a guide rod shaft (51) and a conical body (52), the guide rod shaft is installed in the guide hole, under the impact of airflow, the guide rod shaft can move axially in the guide hole, and the vortex body rotates under the impact of the fluid flow and the airflow. The invention can effectively improve the atomization performance of the nozzle, make the spray atomization granularity finer and improve the atomization uniformity.

Description

A spraying device for textile product production

Technical Field

The invention relates to the technical field of textile product production and manufacturing, in particular to a spraying device for textile product production.

Background

In the production of textile products, jet dyeing is a common dyeing method, and the jet dyeing apparatus comprises a spraying device which sprays color or a treating agent to the textile product/blank through a nozzle. However, the existing spraying device has the problems of larger spraying and atomizing granularity and poorer uniformity.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provide a spraying device for producing textile products, wherein under the impact of air flow, a guide rod shaft of a vortex body can move axially in a guide hole, a flow hole is communicated with a vortex atomizing cavity, and the vortex body (a vortex piece) rotates under the impact of liquid flow and air flow, so that the atomizing performance of a nozzle can be effectively improved, the spray atomizing granularity is finer, the atomizing uniformity is improved, and the dyeing effect of spray dyeing equipment is improved; the air supply is cut off, and the guide rod shaft of the vortex body is reset along the axial direction under the action of the spring under the impact of no air flow. According to the invention, the heating element is arranged on the inner peripheral wall of the outlet section and is arranged in the adjacent rotational flow atomization cavity, so that the temperature control effect can be directly improved, the temperature difference change at the outlet of the nozzle is reduced, and the energy is saved.

In order to achieve the purpose, the invention adopts the technical scheme that:

the utility model provides a spraying device for textile production, its includes the nozzle, and the nozzle includes first barrel (1), second barrel (2), interior bushing (3), a support section of thick bamboo (4), vortex body (5), and the left end of first barrel passes through the step with the right-hand member of second barrel and is connected the location, and first barrel is including linkage segment (11), export section (12), its characterized in that: the inner lining barrel is arranged on the inner peripheral wall of the first barrel, the supporting barrel is arranged on the inner peripheral side of the second barrel and the inner lining barrel, a positioning boss (41) is arranged on the periphery of the supporting barrel, two sides of the positioning boss are respectively abutted to the second barrel and the end portion of the inner lining barrel, a plurality of circulation holes (42) are arranged on the supporting barrel, a guide hole is formed in the center of the supporting barrel, the circulation holes are distributed on the periphery of the guide hole, a connector (16) is connected to the outer peripheral side of the first barrel, a cyclone atomization cavity is formed between the first barrel and the supporting barrel, a vortex body is arranged in the cyclone atomization cavity, the vortex body (5) comprises a guide rod shaft (51) and a conical body (52), the guide rod shaft is installed in the guide hole, under the impact of airflow, the guide rod shaft can axially move in the guide hole, and the vortex body does rotary motion under the impact of the fluid flow and the airflow.

Furthermore, the conical body (52) comprises a connecting shaft (53), a rotational flow piece (54) and fins (55), the connecting shaft is located on one side of the conical body, which is far away from the guide rod shaft, the rotational flow piece is rotatably installed on the connecting shaft, the cross section of the rotational flow piece is of a truncated cone shape or a truncated cone arc-shaped structure, the fins are arranged on the periphery of the rotational flow piece, and the fins are distributed along the circumferential direction.

Further, the fins (55) comprise first fins (551) and second fins (552), the first fins are distributed along the circumferential direction, the second fins are distributed along the circumferential direction, gaps are formed between the first fins and the second fins in the axial direction, in the circumferential direction, the first fins and the second fins are arranged in a staggered and spaced mode, and the first fins and the second fins are arc fins or spiral fins.

Further, the right end of the lining barrel (3) is provided with a transition surface (31), the transition surface is an arc surface or a conical surface, a slit channel is arranged between the left end of the conical body (52) and the transition surface, and the slit channel has a radial width g which is substantially equal to the radial width of the fin (55).

Furthermore, the vortex body (5) further comprises a first connecting piece (56), a second connecting piece (57) and a spring (58), the first connecting piece is installed at the end part of the connecting shaft (53), the first connecting piece comprises a first arc-shaped part (561) and a first thread section, the first connecting piece is connected with an internal thread hole at the end part of the connecting shaft through the first thread section, and the outer surface of the arc-shaped part is in smooth transition with the outer surface of the vortex piece (54); the second connecting piece comprises a second arc-shaped part (571) and a second thread section, the second connecting piece is connected with an internal thread hole at the end part of the guide rod shaft (51) through the second thread section, a spring is sleeved on the periphery of the second thread section, one end of the spring is connected with the stopping end of the second arc-shaped part, the other end of the spring is connected with the end face of the supporting cylinder (4) or the guide rod shaft, and the reset spring is used for resetting the vortex body (5) under the impact of no air flow.

Further, the connecting section (11) and the outlet section (12) are positioned by a positioning bulge (13), the outlet section is provided with an outlet hole (14), and the outlet hole comprises an equal-diameter section and a diffusion section which are sequentially connected; the inner peripheral wall of the outlet section is provided with a heating element (15) which is arranged adjacent to the swirl atomizing chamber.

Further, the radial width g is 0.8 to 1.2 times the radial width H of the fin (55); the peripheral arcuate line of the swirl element (54) is a first arcuate line, the end of which forms with the end of the constant diameter section of the outlet orifice (14) a second arcuate line, the first and second arcuate lines lying substantially on the same smooth arcuate line or on a circular line of substantially the same radius.

Furthermore, the first cylinder (1), the second cylinder (2), the lining cylinder (3) and the supporting cylinder (4) are made of stainless steel, and the vortex body (5) is made of corrosion-resistant engineering plastics; the heating element (15) is arranged in a groove of the inner peripheral wall of the outlet section (12) or is integrally formed in the inner peripheral wall of the outlet section and is connected with a power supply through a lead.

Furthermore, the second cylinder (2) is connected with a high-pressure gas source, the joint (16) is connected with a liquid source, high-pressure gas flows through the second cylinder, and coloring materials or treatment liquid flows through the joint.

According to the spraying device for textile product production, under the impact of air flow, the guide rod shaft of the vortex body can move axially in the guide hole, the circulation hole is communicated with the vortex atomization cavity, and the vortex body (vortex piece) rotates under the impact of liquid flow and air flow, so that the atomization performance of the nozzle can be effectively improved, the spray atomization granularity is smaller, the atomization uniformity is improved, and the dyeing effect of spray dyeing equipment is improved; the air supply is cut off, and the guide rod shaft of the vortex body is reset along the axial direction under the action of the spring under the impact of no air flow. According to the invention, the heating element is arranged on the inner peripheral wall of the outlet section and is arranged in the adjacent rotational flow atomization cavity, so that the temperature control effect can be directly improved, the temperature difference change at the outlet of the nozzle is reduced, and the energy is saved.

Drawings

FIG. 1 is a schematic structural view of a spraying device for textile product production according to the present invention;

FIG. 2 is a schematic structural view of a spraying device for textile product production according to the present invention;

fig. 3 is a schematic structural diagram of a spraying device for textile product production according to the invention.

In the figure: the device comprises a first barrel 1, a second barrel 2, a lining barrel 3, a support barrel 4, a vortex body 5, a connecting section 11, an outlet section 12, a positioning protrusion 13, an outlet hole 14, a heating element 15, a joint 16, a transition surface 31, a positioning boss 41, a circulating hole 42, a guide rod shaft 51, a conical body 52, a connecting shaft 53, a vortex piece 54, a fin 55, a first fin 551, a second fin 552, a first connecting piece 56, a first arc portion 561, a second connecting piece 57, a second arc portion 571 and a spring 58.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1-3, a spraying device for textile production, it includes the nozzle, and the nozzle includes first barrel 1, second barrel 2, interior bushing 3, a support section of thick bamboo 4, vortex body 5, and the left end of first barrel 1 passes through the step with the right-hand member of second barrel 2 to be connected the location, and first barrel 1 includes linkage segment 11, export section 12, its characterized in that: the inner lining cylinder 3 is arranged on the inner peripheral wall of the first cylinder 1, the supporting cylinder 4 is arranged on the inner peripheral sides of the second cylinder 2 and the inner lining cylinder 3, the positioning boss 41 is arranged on the periphery of the supporting cylinder 4, two sides of the positioning boss 41 are respectively abutted to the end portions of the second cylinder 2 and the inner lining cylinder 3, the supporting cylinder 4 is provided with a plurality of circulation holes 42, the center of the supporting cylinder 4 is provided with a guide hole, the circulation holes 42 are distributed on the periphery of the guide hole, the periphery of the first cylinder 1 is connected with the joint 16, a rotational flow atomization cavity is formed between the first cylinder 1 and the supporting cylinder 4, a vortex body 5 is arranged in the rotational flow atomization cavity, the vortex body 5 comprises a guide rod shaft 51 and a conical body 52, the guide rod shaft 51 is arranged in the guide hole, the guide rod shaft 51 can axially move in the guide hole under the impact of airflow, and the vortex body 5 rotates under the impact of the fluid flow and the airflow.

The second cylinder 2 is connected with a high-pressure gas source, the joint 16 is connected with a liquid source, high-pressure gas flows through the second cylinder 2, and liquid such as coloring material or treatment liquid flows through the joint 16. Under the impact of air flow, the guide rod shaft 51 can move axially in the guide hole, and the vortex body 5 rotates under the impact of liquid flow and air flow, so that the atomization performance of the nozzle is improved, the spray atomization granularity is finer, and the atomization uniformity is improved; under the impact of no air flow, the guide rod shaft 51 is axially reset.

Further, the conical body 52 comprises a connecting shaft 53, a rotational flow member 54 and fins 55, the connecting shaft 53 is located on one side of the conical body 52 far away from the guide rod shaft 51, the rotational flow member 54 is rotatably mounted on the connecting shaft 53, the cross section of the rotational flow member 54 is substantially in a truncated cone shape or a truncated cone arc structure, the fins 55 are arranged on the outer periphery of the rotational flow member 54, and the plurality of fins 55 are distributed along the circumferential direction.

The fins 55 include first fins 551 and second fins 552, a plurality of first fins 551 are distributed along the circumferential direction, a plurality of second fins 552 are distributed along the circumferential direction, the first fins 551 and the second fins 552 have gaps in the axial direction, and in the circumferential direction, the plurality of first fins 551 and the plurality of second fins 552 are arranged at intervals in a staggered manner, and the first fins 551 and the second fins 552 are arc fins or spiral fins.

Further, the right end of the liner 3 is provided with a transition surface 31, the transition surface 31 is an arc surface or a conical surface, a slit channel is arranged between the left end of the cone 52 and the transition surface 31, and the slit channel has a radial width g which is substantially equal to the radial width of the fin 55.

The vortex body 5 further comprises a first connecting piece 56, a second connecting piece 57 and a spring 58, wherein the first connecting piece 56 is installed at the end part of the connecting shaft 53, the first connecting piece 56 comprises a first arc-shaped part 561 and a first thread section, the first connecting piece 56 is connected with an internal thread hole at the end part of the connecting shaft 53 through the first thread section, and the outer surface of the arc-shaped part is in smooth transition with the outer surface of the vortex piece 54. The second connecting member 57 includes a second arc-shaped portion 571 and a second thread section, the second connecting member 57 is connected with the internal thread hole at the end of the guide rod shaft 51 through the second thread section, the outer periphery of the second thread section is sleeved with a spring 58, one end of the spring 58 is connected with the stop end of the second arc-shaped portion, the other end is connected with the end surface of the support cylinder 4 or the guide rod shaft 51, and the return spring 58 is used for returning the vortex body 5 under the impact of no air flow. The arc-shaped part is used for reducing fluid resistance and backflow.

The connecting section 11 and the outlet section 12 are positioned by a positioning bulge 13, the outlet section 12 is provided with an outlet hole 14, and the outlet hole 14 comprises an equal-diameter section and a diffusion section which are connected in sequence; the internal perisporium of export section 12 is provided with heating element 15, and heating element 15 sets up in adjoining whirl atomizing chamber, can directly improve the temperature control effect, reduces the nozzle exit difference in temperature change, the energy saving.

As shown in fig. 3, the radial width g is preferably 0.9 to 1.1 times the radial width H of the fin 55, so that the impact swirling effect on the fin 55 is improved while the air flow circulation performance is ensured, thereby improving the atomization effect of the nozzle. The outer circumferential arc of swirl element 54 is a first arc having an end that forms a second arc with the end of the constant diameter section of outlet orifice 14, the first and second arcs being substantially on the same smooth arc or on a circular line of substantially the same radius. The structural design can improve the smoothness of the gas-liquid mixed liquid after swirling to the outlet hole 14, thereby improving the atomization performance of the nozzle.

The material of the nozzle part or all the components is stainless steel and/or corrosion-resistant engineering plastics, for example, the material of the first barrel 1, the second barrel 2, the lining barrel 3 and the support barrel 4 is stainless steel, and the material of the vortex body 5 is corrosion-resistant engineering plastics. The heating element 15 is installed in a groove of the inner peripheral wall of the outlet section 12, or is integrally formed in the inner peripheral wall of the outlet section 12, and is connected with a power supply through a wire.

According to the spraying device for textile product production, under the impact of air flow, the guide rod shaft 51 of the vortex body 5 can move axially in the guide hole, the circulation hole 42 is communicated with the vortex atomization cavity, and the vortex body 5 (the vortex piece 54) rotates under the impact of liquid flow and air flow, so that the atomization performance of a nozzle can be effectively improved, the spray atomization granularity is finer, the atomization uniformity is improved, and the dyeing effect of spray dyeing equipment is improved; the supply of the gas source is cut off and the spindle shaft 51 of the vortex body 5 is axially reset by the spring 58 under the impact of no gas flow. According to the invention, the heating element 15 is arranged on the inner peripheral wall of the outlet section 12, and the heating element 15 is arranged adjacent to the rotational flow atomization cavity, so that the temperature control effect can be directly improved, the temperature difference change at the outlet of the nozzle is reduced, and the energy is saved.

The above-described embodiments are illustrative of the present invention and not restrictive, it being understood that various changes, modifications, substitutions and alterations can be made herein without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. The utility model provides a spraying device for textile production, its includes the nozzle, and the nozzle includes first barrel (1), second barrel (2), interior bushing (3), a support section of thick bamboo (4), vortex body (5), and the left end of first barrel passes through the step with the right-hand member of second barrel and is connected the location, and first barrel is including linkage segment (11), export section (12), its characterized in that: the inner lining barrel is arranged on the inner peripheral wall of the first barrel, the supporting barrel is arranged on the inner peripheral side of the second barrel and the inner lining barrel, a positioning boss (41) is arranged on the periphery of the supporting barrel, two sides of the positioning boss are respectively abutted to the second barrel and the end portion of the inner lining barrel, a plurality of circulation holes (42) are arranged on the supporting barrel, a guide hole is formed in the center of the supporting barrel, the circulation holes are distributed on the periphery of the guide hole, a connector (16) is connected to the outer peripheral side of the first barrel, a cyclone atomization cavity is formed between the first barrel and the supporting barrel, a vortex body is arranged in the cyclone atomization cavity, the vortex body (5) comprises a guide rod shaft (51) and a conical body (52), the guide rod shaft is installed in the guide hole, under the impact of airflow, the guide rod shaft can axially move in the guide hole, and the vortex body does rotary motion under the impact of the fluid flow and the airflow.

2. A spraying device for the production of textile products according to claim 1, characterized in that the cone (52) comprises a connecting shaft (53) which is located on the side of the cone remote from the shaft of the guide rod, a swirl element (54) which is rotatably mounted on the connecting shaft, the cross section of the swirl element being substantially in the form of a truncated cone or a truncated cone arc, the circumference of the swirl element being provided with fins, a plurality of fins being distributed in the circumferential direction.

3. A spraying device for textile product production as set forth in claim 2, characterized in that the fins (55) comprise a first fin (551) and a second fin (552), a plurality of the first fins are distributed along the circumferential direction, a plurality of the second fins are distributed along the circumferential direction, the first fins and the second fins have gaps in the axial direction, and the plurality of the first fins and the plurality of the second fins are arranged at intervals in the circumferential direction, and the first fins and the second fins are arc fins or spiral fins.

4. A spraying device for the production of textile products according to claim 3, characterized in that the right end of the lining cylinder (3) is provided with a transition surface (31) which is an arc-shaped surface or a conical surface, and that a slit channel is provided between the left end of the cone (52) and the transition surface, the slit channel having a radial width g which is substantially equal to the radial width of the fins (55).

5. A spraying device for textile product production as set forth in claim 4, characterized in that the vortex body (5) further comprises a first connecting member (56), a second connecting member (57), a spring (58), the first connecting member being mounted at the end of the connecting shaft (53), the first connecting member comprising a first arc-shaped portion (561) and a first threaded section, the first connecting member being connected with an internally threaded hole at the end of the connecting shaft by the first threaded section, the outer surface of the arc-shaped portion being in smooth transition with the outer surface of the vortex member (54); the second connecting piece comprises a second arc-shaped part (571) and a second thread section, the second connecting piece is connected with an internal thread hole at the end part of the guide rod shaft (51) through the second thread section, a spring is sleeved on the periphery of the second thread section, one end of the spring is connected with the stopping end of the second arc-shaped part, the other end of the spring is connected with the end face of the supporting cylinder (4) or the guide rod shaft, and the reset spring is used for resetting the vortex body (5) under the impact of no air flow.

6. A spraying device for the production of textile products according to claim 5, characterized in that the connecting section (11) and the outlet section (12) are positioned by means of a positioning projection (13), the outlet section having an outlet hole (14) comprising a constant diameter section and a diverging section connected in sequence; the inner peripheral wall of the outlet section is provided with a heating element (15) which is arranged adjacent to the swirl atomizing chamber.

7. A spraying device for the production of textile articles as claimed in claim 5 or 6, characterized in that the radial width g is 0.8-1.2 times the radial width H of the fins (55); the peripheral arcuate line of the swirl element (54) is a first arcuate line, the end of which forms with the end of the constant diameter section of the outlet orifice (14) a second arcuate line, the first and second arcuate lines lying substantially on the same smooth arcuate line or on a circular line of substantially the same radius.

8. A spraying device for textile product production as claimed in claim 5 or 6, characterized in that the materials of the first cylinder (1), the second cylinder (2), the lining cylinder (3) and the support cylinder (4) are stainless steel, the material of the vortex body (5) is corrosion-resistant engineering plastic; the heating element (15) is arranged in a groove of the inner peripheral wall of the outlet section (12) or is integrally formed in the inner peripheral wall of the outlet section and is connected with a power supply through a lead.

9. A spray device for the production of textile products according to claim 1, wherein the second cylinder (2) is connected to a source of high pressure gas, the connection (16) is connected to a source of liquid, high pressure gas is conducted through the second cylinder, and colour or other treatment liquid is conducted through the connection.