CN115467095B - Spraying equipment for processing non-woven fabrics - Google Patents

Abstract

The invention discloses spraying equipment for processing non-woven fabrics, which comprises a conveying mechanism, limiting plates arranged on two sides of the conveying mechanism, a spraying area arranged on the conveying mechanism, a prewetting frame arranged on the conveying mechanism and positioned on one side of the spraying area, a prewetting spray head arranged in the prewetting frame, and a detection assembly arranged on the limiting plates, wherein the limiting plates are arranged on the conveying mechanism; a power assembly disposed within the prewetting frame; the auxiliary testing component is arranged in the prewetting frame, the non-woven fabrics can be detected by the aid of the detecting component, labor workload of workers is reduced, thickness measuring work can be completed during transportation, efficiency is improved, corresponding electric signals are sent to the power component through the detecting component after thickness detection is completed, the position of the prewetting spray head is controlled to be correspondingly adjusted, and the prewetting spray head is guaranteed to be located at a spraying optimal position.

Description

Spraying equipment for processing non-woven fabrics

Technical Field

The invention relates to the technical field of non-woven fabric processing, in particular to spraying equipment for non-woven fabric processing.

Background

The non-woven fabric is also called non-woven fabric, needled cotton, needled non-woven fabric and the like, is produced by adopting polyester fiber and polyester fiber materials and is manufactured by a needling process, can be made into different thicknesses, handfeel, hardness and the like, has the characteristics of moisture resistance, ventilation, flexibility, lightness, thinness, flame retardance, no toxicity, no smell, low price, recycling and the like, is relatively convenient compared with other fabrics when the non-woven fabric is cut and sewn due to no warps and wefts, has light weight and is easy to shape, and the non-woven fabric production method mainly comprises the following steps: needling, imitation bonding, hot-melt, etc., and the general market usage is large for nonwoven fabrics produced by needling;

the spun-laced non-woven fabric is a fabric processed by a spun-laced method, the principle is that high-pressure micro water flow is utilized to spray the fibers onto a fiber web, the fibers are displaced under the action force of water flow penetration, entanglement and cohesion are started, the fibers are twisted into a strand, the fiber web is reinforced, compared with the common non-woven fabric, the fiber web is stronger, the flexibility of the fibers is not damaged in the processing process, the air permeability is also good, and the general process flow for producing the non-woven fabric reinforcement by the spun-laced method is as follows: fiber forming, prewetting, multi-channel water jet on the front and back, pattern water jet, dewatering, predrying, post finishing, drying and shaping, slitting, winding and packaging;

chinese application CN210657521U discloses a non-woven fabric spraying device, which can change the spraying area according to the size of the non-woven fabric, so as to effectively avoid waste caused by excessive use of liquid materials used in spraying or the phenomenon that the liquid materials are too little to need to be sprayed for many times, and greatly improve the spraying efficiency;

in the actual operation process, the thickness of the same batch of non-woven fabrics is generally the same, although the spraying area can be changed according to the size of the non-woven fabrics, the thickness of the non-woven fabrics of the next batch may be changed when the non-woven fabrics of the next batch are sprayed, the water jet pressure required by the non-woven fabrics with different thicknesses in the spraying process is correspondingly different, the non-woven fabrics need to be wetted in advance when the non-woven fabrics are sprayed (the fiber web can absorb water jet energy as much as possible when the non-woven fabrics are sprayed, the water jet effect is increased), the water needle is in a vertical state with the non-woven fabrics as much as possible when the non-woven fabrics are wetted (the position of a spray head is required to be adjusted sometimes), and when the non-woven fabrics with the changed thickness are sprayed, the distance between the water needle of a spraying part and the non-woven fabrics is correspondingly changed, so that the situation that the fiber web is flung (the water jet pressure is too high) or the spraying effect is not good (the water jet pressure is too low) is easy to occur when the non-woven fabrics are still at the same at the moment, so as to influence the processing quality of the non-woven fabrics.

Disclosure of Invention

The invention aims to provide spraying equipment for processing non-woven fabrics, so as to solve the problems in the prior art.

In order to achieve the above purpose, the present invention provides the following technical solutions: the spray equipment for processing the non-woven fabrics comprises a conveying mechanism, limit plates arranged on two sides of the conveying mechanism, a spray area arranged on the conveying mechanism, and a prewetting frame arranged on the conveying mechanism and positioned on one side of the spray area, wherein prewetting spray heads used for carrying out prewetting operation on the non-woven fabrics are arranged in the prewetting frame, and the spray equipment further comprises detection components arranged on the limit plates and used for measuring the thickness of the non-woven fabrics; the power assembly is arranged in the prewetting frame and used for adjusting the position of the prewetting nozzle; the auxiliary testing component is arranged in the prewetting frame and used for detecting the water jet pressure of the prewetting nozzle after position adjustment.

Preferably, the detection assembly comprises an inclined groove body, a rubber ball group, a plastic connecting rod, a sliding roller and a clamping piece, wherein the inclined groove body is arranged on the side wall of the limiting plate; the rubber ball group is arranged on one side of the limiting plate and is positioned above the conveying mechanism; the plastic connecting rods are arranged on two sides of the rubber ball group and are in sliding connection with the inclined groove body; the sliding rollers are arranged at two ends of the plastic connecting rod and are in sliding connection with the inclined groove body; the clamping piece is arranged inside the limiting plate and used for measuring the thickness of the non-woven fabric through the stay position of the sliding roller.

Preferably, the clamping piece comprises an action block arranged inside the limiting plate, the action block is internally provided with a plurality of action blocks, the end parts of the action blocks penetrate through the inner wall of the limiting plate and extend to the inner wall of the inclined groove body, the end parts of the action blocks are arranged in a circular arc shape and higher than the inner wall of the inclined groove body, the clamping groove bodies are arranged on the action blocks, the inner wall of the limiting plate is provided with a fixing seat, a rotating rod used for rotating and connecting the action blocks is arranged on the fixing seat, the end parts of the rotating rod are in sliding connection with the clamping groove bodies, a reset spring is connected between the inner wall of the limiting plate and the other end of the action block, and a trigger button is arranged on the action block.

Preferably, the clamping groove body is composed of a clamping area, a descending area and an ascending area, wherein one end of the acting block, which is far away from the inclined groove body, is a magnetic end, and a strip electromagnet is arranged on the inner wall of the limiting plate.

Preferably, the power component comprises a mounting plate arranged inside the prewetting frame, the mounting plate is used for supporting the prewetting nozzle, the top of the prewetting frame is provided with a supporting frame, the mounting plate is provided with a supporting rod frame, the end part of the supporting rod frame penetrates through the inner wall of the prewetting frame and extends into the supporting frame, the end part of the supporting rod frame is provided with a fixing plate, the two ends of the fixing plate are provided with roller bodies, the top of the supporting frame is fixedly provided with a motor body, the output end of the motor body penetrates through the outer wall of the supporting frame and extends into the inner part of the supporting frame, and the output end of the motor body is provided with a transmission piece.

Preferably, the transmission piece is including setting up in the pinion of motor body output, and be provided with drive gear in the braced frame is inside taking the central line of motor body output as the axis to be the symmetry, be provided with the rotation post on the drive gear, just rotate post end connection in braced frame top inner wall and rotate with it between and be connected, just the braced frame is inside to be provided with fixed slide rail as the axis with the central line of motor body output for the axis symmetry, and be provided with in the fixed slide rail and be used for carrying out the circular sleeve of rotating connection between it, just rotate post end connection in circular sleeve inner wall, and be provided with annular spout in the circular sleeve.

Preferably, a spiral slide rail is arranged in the annular slide groove, the roller body is in sliding connection with the spiral slide rail, and a parking button is arranged at the end part of the spiral slide rail.

Preferably, the auxiliary test assembly comprises a pressure test plate, a pressure sensor, a circular groove, a transverse connecting plate, an electromagnet body, a magnet piece, a transverse groove and an adjusting groove, wherein the pressure test plate is arranged inside the prewetting frame and is positioned below the mounting plate; the pressure sensors are arranged on the pressure test plate and are provided with a plurality of pressure sensors; the circular grooves are arranged on the pressure test plate and are provided with a plurality of grooves; the transverse connecting plate is arranged on the supporting rod frame, a plurality of telescopic rods used for sliding connection with the transverse connecting plate are arranged on the transverse connecting plate, and the end parts of the telescopic rods are connected to the pressure test plate; the electromagnet body is arranged on the mounting plate and provided with a plurality of electromagnet bodies; the magnet piece is arranged on the pressure test plate and provided with a plurality of magnets; the transverse groove is arranged on the mounting plate and is in sliding connection with the telescopic rod; the adjusting groove is arranged on the lateral wall of the transverse groove and is in sliding connection with the telescopic rod.

Compared with the prior art, the invention has the beneficial effects that:

according to the invention, the non-woven fabrics with different thicknesses can be detected by utilizing the detection assembly, so that the labor workload of workers is reduced, the thickness measurement work can be finished in the transportation process, the efficiency is improved, the detection assembly is utilized to send corresponding electric signals to the power assembly after the thickness detection is finished, the position of the prewetting spray head is controlled to be correspondingly adjusted, the prewetting spray head is ensured to be at the optimal spraying position, the water jet pressure is measured by the auxiliary test assembly, and the water jet pressure can be effectively ensured to be in accordance with the absorption range of the non-woven fabrics fiber web in the spraying process.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic view of a partial structure of the present invention;

FIG. 3 is a schematic diagram of a detecting assembly according to the present invention;

FIG. 4 is a schematic view of a clip according to the present invention;

FIG. 5 is a schematic view of the structure of the clamping member after the limiting plate is removed;

FIG. 6 is a schematic diagram of the front structure of the clamping member according to the present invention;

FIG. 7 is a schematic cross-sectional view of a part of the structure of the present invention;

FIG. 8 is a schematic diagram of a power assembly of the present invention;

FIG. 9 is a schematic view of a partial construction of a power assembly and auxiliary test assembly according to the present invention;

FIG. 10 is a schematic diagram of a driving member according to the present invention;

FIG. 11 is a schematic view of a partial structure of a driving member according to the present invention;

FIG. 12 is a schematic diagram of the front structure of the power module and auxiliary test module of the present invention;

FIG. 13 is a schematic view of an auxiliary test assembly according to the present invention;

FIG. 14 is a schematic view of a partial structure of an auxiliary test assembly according to the present invention;

fig. 15 is an enlarged view showing the structure of the area a in fig. 3 according to the present invention.

In the figure: 1-a transport mechanism; 2-limiting plates; 3-spraying area; 4-prewetting the frame; 5-prewetting the spray head; 6-a detection assembly; 7-a power assembly; 8-auxiliary test assembly; 61-tilting a tank body; 62-a set of rubber spheres; 63-plastic connecting rods; 64-sliding roller; 65-clamping piece; 71-a mounting plate; 72-a support frame; 73-supporting a rod rack; 74-a fixed plate; 75-roller body; 76-motor body; 77-a transmission member; 81-a pressure test plate; 82-a pressure sensor; 83-a circular groove; 84-transverse connection plates; 85-an electromagnet body; 86-magnet piece; 87-transverse grooves; 88-an adjustment tank; 89-telescoping rod; 651-action block; 652-clamping the groove body; 653-a holder; 654—rotating a rod; 655-a return spring; 656-trigger button; 657-clamping area; 658-a drop zone; 659-rise region; 650-bar electromagnet; 771-small gear; 772-a drive gear; 773-turning the column; 774-fixing the slide rail; 775-circular sleeve; 776-annular chute; 777-spiral slide rail; 778-park button.

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.

Referring to fig. 1-15, the present invention provides a technical solution: the spray equipment for processing the non-woven fabrics is correspondingly improved according to the technical problems recorded in the background technology; the non-woven fabric pre-wetting machine comprises a conveying mechanism 1, limiting plates 2 fixedly arranged on two sides of the conveying mechanism 1, a spraying area 3 arranged on the conveying mechanism 1, and a pre-wetting frame 4 arranged on the conveying mechanism 1, wherein the pre-wetting frame 4 is positioned on one side of the spraying area 3, non-woven fabrics need to pass through the pre-wetting frame 4 and then are conveyed to the spraying area 3 for spraying, and a pre-wetting spray head 5 for pre-wetting the non-woven fabrics is arranged inside the pre-wetting frame 4;

when the non-woven fabrics of the same batch are sprayed, the thickness of the non-woven fabrics of the next batch may be changed, and in order to improve the prewetting and spraying effects, the thickness of the non-woven fabrics needs to be measured, and furthermore, the detection assembly 6 for measuring the thickness of the non-woven fabrics is arranged on the limiting plate 2, and the detection assembly 6 performs measurement work in the non-woven fabric transportation process, so that the workload of workers is reduced on one hand, and the transportation of the non-woven fabrics is not delayed on the other hand; in order to enable the prewetting water needle sprayed by the prewetting spray head 5 to be in a vertical condition as far as possible with the non-woven fabric, and further after the thickness is changed, the position of the prewetting spray head 5 needs to be correspondingly adjusted, a power assembly 7 for adjusting the position of the prewetting spray head 5 is arranged in the prewetting frame 4; after the prewetting spray head 5 is adjusted, in order to ensure that the water jet pressure of prewetting and subsequent spraying work is in a normal range, an auxiliary test assembly 8 for detecting the water jet pressure of the prewetting spray head 5 after position adjustment is arranged in the prewetting frame 4, so that the prewetting water needle is in a vertical state with the non-woven fabric as much as possible in the prewetting and spraying process.

Specifically, after spraying the same batch of non-woven fabrics, spraying the non-woven fabrics in the next batch, placing the non-woven fabrics on a conveying mechanism 1, synchronously moving the non-woven fabrics along with the conveying mechanism 1, detecting the thickness of the non-woven fabrics under the action of a detection component 6 in the conveying process, controlling the power component 7 to drive a pre-wetting spray head 5 to perform corresponding position adjustment by the detection component 6 by sending a corresponding electric signal to the power component 7, and simultaneously, in the position adjustment process of the pre-wetting spray head 5, correspondingly adjusting the auxiliary test component 8 along with the pre-wetting spray head 5, and after the position adjustment of the pre-wetting spray head 5 is completed, measuring the water penetration pressure by the auxiliary test component 8 so as to ensure that the non-woven fabrics can fully absorb water penetration energy during the pre-wetting and subsequent spraying operation, thereby improving the production efficiency;

further, this scheme utilizes detection component 6 can detect the non-woven fabrics of different thickness, on the one hand reduces staff's work load, on the other hand can accomplish thickness measurement work in transit, and efficiency is improved, utilize detection component 6 to send corresponding signal to power component 7 after accomplishing through thickness detection, utilize power component 7 can carry out corresponding adjustment to the position of prewetting shower nozzle 5, ensure that prewetting shower nozzle 5 is in spraying the optimal position, so that the non-woven fabrics can effectively absorb water thorn energy, survey water thorn pressure through auxiliary test component 8, can effectively ensure to spray the in-process, water thorn pressure accords with the absorption scope of non-woven fabrics web.

As shown in fig. 2-6: as a further limitation of the present solution, the detecting component 6 in the present solution includes an inclined groove 61 disposed on a side wall of the limiting plate 2, the inclined groove 61 is disposed obliquely upward on the limiting plate 2, and a rubber ball group 62 is disposed on one side of the limiting plate 2, wherein the rubber ball group 62 is located above the transporting mechanism 1, a distance between the rubber ball group 62 and the transporting mechanism 1 can be directly set (needs to be close to the transporting mechanism 1 but not contact with the transporting mechanism), so as to ensure that the rubber ball group 62 is at a fixed value, and plastic connecting rods 63 for sliding connection with the inclined groove 61 are connected to two sides of the rubber ball group 62, which further illustrates that, in general, in order to improve overall working efficiency during processing of non-woven fabrics, a certain amount of non-woven fabrics are generally stacked (not single non-woven fabrics are transported), and further the non-woven fabrics in the spraying process have thickness variation, however, in general, the thickness of the non-woven fabric is relatively thicker, the sliding rollers 64 are installed at both ends of the plastic connecting rod 63 and are rotatably connected with the sliding rollers 64, the sliding rollers 64 are slidably connected with the inner wall of the inclined groove body 61, and the clamping pieces 65 for measuring the thickness of the non-woven fabric by the stay positions of the sliding rollers 64 are arranged in the limiting plate 2, so that the surface of the non-woven fabric acts on the rubber ball group 62 during transportation, the plastic connecting rod 63 synchronously acts with the non-woven fabric, the rubber ball group 62 can synchronously act with the non-woven fabric due to the fact that the non-woven fabric has a certain thickness, the sliding rollers 64 at both ends of the plastic connecting rod 63 directionally act along the inclined groove body 61 during movement, the inclined groove body 61 is obliquely upwards, and the rubber ball group 62 is further directionally lifted, the position where the sliding roller 64 stays is not only the thickness measuring position of the non-woven fabric, but also the thickness of the non-woven fabric is measured correspondingly under the action of the clamping piece 65;

the clamping piece 65 in the scheme comprises a plurality of action blocks 651 installed inside the limiting plate 2, wherein the action blocks 651 are installed inside the limiting plate 2, the plurality of action blocks 651 form the same inclination angle as the inclined groove body 61, the action blocks 651 are at the same interval, the interval between the action blocks 651 is not only the thickness interval of non-woven fabrics (the interval between the action blocks 651 is the radius of the sliding roller 64), the end parts of the action blocks 651 penetrate through the inner wall of the limiting plate 2 and extend to the inner wall of the inclined groove body 61, the end parts of the action blocks 651 are arc-shaped and slightly higher than the inner wall of the inclined groove body 61 (the sliding roller 64 acts on the end parts of the action blocks 651 in the process of directional movement along the inclined groove body 61 so as to enable the action blocks 651 to be contracted into the inside of the limiting plate 2 under acting force), the action blocks 651 are provided with clamping groove bodies 652, the clamping groove body 652 is composed of a clamping area 657, a descending area 658 and an ascending area 659, a fixed seat 653 is fixedly arranged on the inner wall of the limiting plate 2, a rotating rod 654 used for rotating and connecting the fixed seat 653 is arranged on the fixed seat 653, the end part of the rotating rod 654 is in sliding connection with the clamping groove body 652, a return spring 655 is connected between the inner wall of the limiting plate 2 and the other end of the acting block 651, a trigger button 656 is arranged on each acting block 651, the trigger buttons 656 on each acting block 651 correspond to different electric signals (different electric signals correspond to different thickness intervals), one end of the acting block 651 away from the inclined groove body 61 is a magnetic end, and a bar electromagnet 650 is fixedly arranged on the inner wall of the limiting plate 2, namely the bar electromagnet 650 is in a different attraction state to the magnetic end of the acting block 651;

specifically, in the course of the directional movement of the slide roller 64 along the inclined groove body 61 under the action of the plastic tie rod 63, the slide roller 64 acts on the acting block 651 along the way, the acting block 651 along the way is contracted into the inside of the limiting plate 2 by the action force, the end of the rotating rod 654 in the initial state is located in the clamping area 657 of the clamping groove body 652 (i.e., the junction between the tail end of the ascending area 659 and the initial end of the descending area 658), when the acting block 651 is contracted into the inside of the limiting plate 2 by the action force, the return spring 655 is compressed in the middle, the rotating rod 654 enters the initial stage of the descending area 658 along the clamping area 657, at this time, the fixed state of the acting block 651 contacts, the acting block 651 acts into the inclined groove body 61 under the action of the return spring 655, and the rotating rod is directionally moved along the clamping groove body 652 (from the initial stage of the descending area 658 to the tail end at this time and at the initial end of the ascending area 659), and the trigger button 656 on the acting block 651 enters the inclined groove body 61 to block the initial stage of the acting block 651 and acts to the slide roller 64; the sliding roller 64 applies force to the acting block 651 along the way in the moving process, so that the sliding roller 64 performs the actions, most of the area is located in the inclined groove body 61 after each limiting block passes, the trigger button 656 is exposed in the descending path of the sliding roller 64, when the non-woven fabric no longer acts on the rubber roller group, the sliding roller 64 is not acted on the acting force, when the sliding roller 64 descends along the inclined groove body 61 under the action of gravity, the sliding roller 64 touches the trigger button 656 on the limiting block of the area, and the area corresponds to the thickness of the non-woven fabric batch at the moment and sends a corresponding signal to the power assembly 7.

As shown in fig. 7-11: as a further limitation of the present solution, the power assembly 7 in the present solution includes a mounting plate 71 disposed inside the pre-wetting frame 4, and the mounting plate 71 is used for supporting the pre-wetting nozzle 5 (the pre-wetting nozzle 5 is mounted on the mounting plate 71), the top of the pre-wetting frame 4 is fixedly mounted with a supporting frame 72, further illustrating that the inclined groove 61 is located at a certain distance from the pre-wetting frame 4 to ensure that the non-woven fabric can be restored to a normal shape, generally speaking, the non-woven fabric cannot be changed in a too large shape, wherein the mounting plate 71 is fixedly mounted with a supporting rod frame 73, and the end of the supporting rod frame 73 extends through the inner wall of the pre-wetting frame 4 and into the supporting frame 72, further illustrating that the supporting rod frame 73 can be correspondingly slidably connected with the inner wall of the pre-wetting frame 4, and a fixing plate 74 is mounted at the end of the supporting rod frame 73 (the fixing plate 74 is located inside the supporting frame 72), the roller bodies 75 are installed at two ends of the fixed plate 74, the motor body 76 is fixedly installed at the top of the supporting frame 72, further explaining that the electric signal sent by the trigger button 656 on each action block 651 corresponds to the rotation number of the motor body 76, and in the scheme, the action block 651 and the trigger button 656 are provided with six, the first three (near the initial end of the inclined groove body 61) represent the clockwise rotation of the motor body 76, the last three represent the anticlockwise rotation of the motor body 76, the specific number can be specifically set according to the site use condition, the output end of the motor body 76 penetrates through the outer wall of the supporting frame 72 and extends to the inside, and the transmission member 77 is arranged at the output end of the motor body 76, the transmission member 77 in the scheme comprises a small gear 771 fixedly installed at the output end of the motor body 76, the transmission gear 772 is symmetrically arranged in the supporting frame 72 by taking the central line of the output end of the motor body 76 as an axis, the small gear 771 and the transmission gear 772 are in a meshed state, the number of teeth and the radius of the small gear 771 are smaller than those of the transmission gear 772, a rotating column 773 is fixedly arranged on the transmission gear 772, the end part of the rotating column 773 is connected to the inner wall of the top of the supporting frame 72 and is in rotating connection with the supporting frame, a fixed sliding rail 774 is symmetrically arranged in the supporting frame 72 by taking the central line of the output end of the motor body 76 as an axis, the fixed sliding rail 774 is fixedly arranged on the inner wall of the supporting frame 72, a circular sleeve 775 for rotating connection with the fixed sliding rail 774 is arranged in the fixed sliding rail 774, the end part of the rotating column 773 is connected to the inner wall of the circular sleeve 775, a circular sliding groove 776 is arranged in the circular sleeve 775, a spiral sliding rail 777 is fixedly arranged in the transmission gear 776, the inner part of the circular sliding groove 777, the roller body 75 is in sliding connection with the spiral sliding rail 777, an initial parking button 778 for controlling the stopping of the motor body 76 is arranged at the end part of the spiral sliding rail 777, and the initial parking state is in a state, namely, the spiral sliding rail 75 is in a clockwise descending state, namely, the middle position is in a clockwise descending state, namely, the rolling rail 75 moves upwards;

specifically, when the sliding roller 64 acts on the trigger button 656 on one of the limiting blocks, the area corresponds to the thickness of the batch of non-woven fabrics at this time, and a corresponding signal is sent to the motor body 76 through the trigger button 656, the rotation direction and the rotation number of turns of the motor body 76 are determined, and in the rotation process of the motor body 76, the output end of the motor body is meshed with the driving gear 772 through the small gear 771 so as to drive the driving gear 772 to rotate, thereby driving the circular sleeve 775 to directionally rotate in the fixed sliding rail 774 under the action of the rotating column 773, and in the rotation process, the spiral sliding rail 777 acts on the roller body 75 to enable the roller body 75 to ascend or descend.

As shown in fig. 12-14: as a further limitation in this scenario: the auxiliary test assembly 8 comprises a pressure test plate 81 arranged inside the pre-wetting frame 4 and positioned below the mounting plate 71, wherein a plurality of pressure sensors 82 for testing the water jet pressure are arranged on the pressure test plate 81, a circular groove 83 is arranged on one side of the pressure sensors 82, namely the pressure test plate 81, the radius (or the size) of the circular groove 83 is slightly larger than that of the pre-wetting spray head 5, a transverse connecting plate 84 is fixedly arranged on the support rod frame 73, a telescopic rod 89 for sliding connection with the transverse connecting plate 84 is arranged on the transverse connecting plate 84, the end part of the telescopic rod 89 is connected to the surface of the pressure test plate 81, a plurality of transverse grooves 87 are arranged on the mounting plate 71, the output end part of the telescopic rod 89 (namely the connecting rod in contact with the pressure test plate 81) is partially positioned in the transverse grooves 87 and is in sliding connection with the transverse grooves, an adjusting groove 88 is arranged in the transverse groove 87, the adjusting groove 88 is in an oblique upper shape, a sliding column in sliding connection with the adjusting groove 88 is arranged on the output end of the telescopic rod 89, a plurality of electromagnet bodies 85 are fixedly arranged on the mounting plate 71, and a plurality of electromagnet bodies 85 are fixedly arranged between the electromagnet bodies 85 and the electromagnet bodies 85 are fixedly arranged on the electromagnet bodies 85.

Specifically, because the pressure test board 81 is connected with the transverse connection board 84 through the telescopic rod 89, and then when the support rod frame 73 drives the mounting board 71 to lift, the pressure test board 81 moves synchronously along with the support rod frame 73, in the detection process, the pre-wetting spray head 5 sprays, and acts on the pressure sensor 82, when the detection pressure is qualified, both the electric signal is sent to the electromagnet body 85, the electromagnet body 85 provides the attraction force for the magnet piece 86 on the pressure test board 81, so that the pressure test board 81 moves upwards in a fixed direction under the action of the telescopic rod 89, in the lifting process, the sliding column on the telescopic rod 89 moves upwards along the adjusting groove 88 (the telescopic rod 89 and the pressure test board 81 move transversely, and meanwhile, the output end of the telescopic rod 89 and the pressure test board 81 also move upwards), so as to drive the pressure sensor 82 on the pressure test board 81 to move to the position between the pre-wetting spray heads 5, and the pre-wetting spray head 5 moves into the circular groove 83, thereby ensuring that the pre-wetting spray head 5 can pre-wet the non-woven fabric.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a non-woven fabrics processing is with spraying equipment, includes transport mechanism (1), sets up limiting plate (2) in transport mechanism (1) both sides, set up in spray region (3) on transport mechanism (1) with set up in transport mechanism (1) go up and lie in prewetting frame (4) of spray region (3) one side, its characterized in that: the inside prewetting shower nozzle (5) that are used for carrying out the work of prewetting to the non-woven fabrics that is provided with of prewetting frame (4), still include: the detection component (6) is arranged on the limiting plate (2) and used for measuring the thickness of the non-woven fabric;

the power assembly (7) is arranged in the prewetting frame (4) and is used for adjusting the position of the prewetting spray head (5);

the auxiliary testing component (8) is arranged in the prewetting frame (4) and used for detecting the water jet pressure of the prewetting spray head (5) after the position adjustment;

the detection assembly (6) comprises an inclined groove body (61), a rubber ball group (62), a plastic connecting rod (63), a sliding roller (64) and a clamping piece (65), wherein the inclined groove body (61) is arranged on the side wall of the limiting plate (2);

the rubber ball group (62) is arranged on one side of the limiting plate (2) and is positioned above the conveying mechanism (1);

the plastic connecting rods (63) are arranged on two sides of the rubber ball group (62) and are in sliding connection with the inclined groove body (61);

the sliding rollers (64) are arranged at two ends of the plastic connecting rod (63) and are in sliding connection with the inclined groove body (61);

the clamping piece (65) is arranged in the limiting plate (2) and is used for measuring the thickness of the non-woven fabric through the stay position of the sliding roller (64);

the clamping piece (65) comprises action blocks (651) arranged inside the limiting plate (2), a plurality of action blocks (651) are arranged inside the limiting plate (2), the end parts of the action blocks (651) penetrate through the inner wall of the limiting plate (2) and extend to the inner wall of the inclined groove body (61), the end parts of the action blocks (651) are arranged to be circular arcs and higher than the inner wall of the inclined groove body (61), clamping groove bodies (652) are arranged on the action blocks (651), fixing seats (653) are arranged on the inner wall of the limiting plate (2), rotating rods (654) used for rotating connection with the fixing seats (653) are arranged on the fixing seats (653), the end parts of the rotating rods (654) are connected with the clamping groove bodies (652) in a sliding mode, reset springs (655) are connected between the inner wall of the limiting plate (2) and the other end parts of the action blocks (651), and trigger buttons (656) are arranged on the action blocks (651);

the clamping groove body (652) is composed of a clamping area (657), a descending area (658) and an ascending area (659), wherein one end, far away from the inclined groove body (61), of the acting block (651) is a magnetic end, and a strip electromagnet (650) is arranged on the inner wall of the limiting plate (2).

2. The shower apparatus for processing nonwoven fabric according to claim 1, wherein: the power assembly (7) comprises a mounting plate (71) arranged inside the pre-wetting frame (4), the mounting plate (71) is used for supporting the pre-wetting spray head (5), a supporting frame (72) is arranged at the top of the pre-wetting frame (4), a supporting rod frame (73) is arranged on the mounting plate (71), the end part of the supporting rod frame (73) penetrates through the inner wall of the pre-wetting frame (4) and extends into the supporting frame (72), a fixing plate (74) is arranged at the end part of the supporting rod frame (73), roller bodies (75) are arranged at the two ends of the fixing plate (74), a motor body (76) is fixedly arranged at the top of the supporting frame (72), the output end of the motor body (76) penetrates through the outer wall of the supporting frame (72) and extends into the inner part, and a transmission piece (77) is arranged at the output end of the motor body (76).

3. The shower apparatus for processing nonwoven fabric according to claim 2, wherein: the transmission piece (77) is including setting up in small-size gear (771) of motor body (76) output, and be in inside taking the central line of motor body (76) output to be the symmetry and be provided with drive gear (772) of braced frame (72), be provided with on drive gear (772) and rotate post (773), just rotate post (773) end connection in braced frame (72) top inner wall and rotate with between them and be connected, just be provided with fixed slide rail (774) inside taking the central line of motor body (76) output to be the symmetry as the axis, and be provided with in fixed slide rail (774) be used for with between them rotate circular sleeve (775) of being connected, just rotate post (773) end connection in circular sleeve (775) inner wall, and be provided with annular spout (776) in circular sleeve (775).

4. The shower apparatus for nonwoven fabric processing according to claim 3, wherein: the annular chute (776) is internally provided with a spiral slide rail (777), the roller body (75) is in sliding connection with the spiral slide rail (777), and a parking button (778) is arranged at the end part of the spiral slide rail (777).

5. The shower apparatus for processing nonwoven fabric according to claim 2, wherein: the auxiliary test assembly (8) comprises a pressure test plate (81), a pressure sensor (82), a circular groove (83), a transverse connecting plate (84), an electromagnet body (85), a magnet piece (86), a transverse groove (87) and an adjusting groove (88), wherein the pressure test plate (81) is arranged inside the prewetting frame (4) and is positioned below the mounting plate (71);

the pressure sensor (82) is arranged on the pressure test plate (81) and is provided with a plurality of pressure sensors;

the circular grooves (83) are arranged on the pressure test plate (81) and are provided with a plurality of grooves;

the transverse connecting plate (84) is arranged on the supporting rod frame (73), a plurality of telescopic rods (89) which are used for sliding connection with the transverse connecting plate (84) are arranged on the transverse connecting plate (84), and the end parts of the telescopic rods (89) are connected to the pressure test plate (81);

the electromagnet body (85) is arranged on the mounting plate (71) and is provided with a plurality of electromagnet bodies; the magnet pieces (86) are arranged on the pressure test plate (81) and are provided with a plurality of magnet pieces;

the transverse groove (87) is arranged on the mounting plate (71) and is in sliding connection with the telescopic rod (89);

the adjusting groove (88) is arranged on the side wall of the transverse groove (87) and is in sliding connection with the telescopic rod (89).