CN219785255U - Continuous production line of anti-fingerprint hairline corrosion resistant plate - Google Patents

Abstract

The utility model discloses a continuous production line of an anti-fingerprint hairline stainless steel plate, which sequentially comprises an uncoiling mechanism, a leveling mechanism, a bottom polishing mechanism, a wet-milling wire drawing mechanism, a cleaning and drying mechanism, an anti-fingerprint coating roller coating mechanism, a coating heating mechanism, a cooling mechanism, a film covering mechanism and an uncoiling and cutting mechanism, wherein the anti-fingerprint coating roller coating mechanism comprises a roller coating section, the anti-fingerprint coating roller coating mechanism further comprises a filling section arranged in front of the roller coating section, the filling section comprises a conveying unit capable of conveying along the x-axis direction, a spraying unit erected above the conveying unit, a scraping plate unit arranged below the spraying unit and coating collecting units arranged on two sides of the scraping plate unit, and the scraping plate unit comprises a coating capable of blocking the coating sprayed on the surface of the steel plate from moving along the conveying direction of the steel plate.

Description

Continuous production line of anti-fingerprint hairline corrosion resistant plate

Technical Field

The utility model relates to the technical field of stainless steel plate surface hairline treatment and anti-fingerprint treatment equipment, in particular to a continuous production line of an anti-fingerprint hairline stainless steel plate.

Background

Stainless steel plates with wire drawing effects are often used on the surfaces of products such as household appliances, kitchen and bathroom houses and the like, so that the products have hairline and relatively good decorative effects. However, the stainless steel plate is easy to be stained on the surface after wiredrawing treatment, and marks such as fingerprints and palm marks are easy to be left, so that the appearance in use is affected. Therefore, the prior art provides a hairline stainless steel plate with an anti-fingerprint effect, which not only can achieve the decorative effect of hairlines, but also can avoid the influence on the appearance caused by leaving marks such as fingerprints, palm prints and the like.

The manner of anti-fingerprint treatment of stainless steel plates with hairline surfaces generally comprises two methods of coating anti-fingerprint paint and vacuum coating anti-fingerprint coating. The technical scheme of coating the anti-fingerprint coating is recorded in the utility model patent with the publication number of CN107776947B and the name of anti-fingerprint steel plate production line in Chinese patent database, and the technical scheme of coating the anti-fingerprint coating on the surface of the dried stainless steel plate in a roller coating way. The manufacturing cost is relatively low, the production efficiency is relatively high, but when the surface of the hairline stainless steel plate with relatively deep wire drawing depth is coated by roller, the section which is only heated and leveled is insufficient for completely exchanging the paint with the air in the hairline formed by wire drawing due to the fact that the paint has certain tension, namely the air which is not exhausted is remained in the hairline. This (1) tends to form bubbles in the cured coating, (2) affects the adhesion of the coating to the surface of the stainless steel sheet, and (3) the risk that the air which is not exhausted may attack the hairline which is not subjected to any protective treatment.

The technical scheme of the vacuum coating anti-fingerprint coating is recorded in the utility model patent with publication number CN104694929B in Chinese patent database, named as a method for preparing anti-fingerprint coating on the surface of a bathroom product, which is to remove oil on the surface of a substrate with wire drawing lines after nickel plating, and then sequentially carrying out vacuum coating of a corrosion-resistant alloy coating layer, vacuum coating of a color layer, intermediate frequency magnetron sputtering of a transparent silicon oxide film and vacuum evaporation of a fluorine polymer transparent nano anti-fingerprint coating layer to prepare the anti-fingerprint coating on the surface of the bathroom product. According to the technical scheme, the adhesion effect of each film layer or coating and the stainless steel plate is better, and the coating film or coating can be completely filled in the hairline, so that the film forming effect of the coating film or coating is better, and the action time of the protective effect on the stainless steel plate is longer. However, the vacuum coating treatment equipment is tank equipment, the treatment efficiency is low, and some production safety hazards easily exist.

In summary, there is a lack of a continuous production line capable of performing anti-fingerprint treatment on the surface of a hairline stainless steel plate with a deep wire drawing depth, i.e. a deep hairline, in the prior art, and the production efficiency is relatively high, and the anti-fingerprint protection service life of the prepared anti-fingerprint hairline stainless steel plate is relatively long.

Disclosure of Invention

The utility model aims to overcome at least one technical problem and provide a continuous production line of the fingerprint-resistant hairline stainless steel plate.

In one aspect of the utility model, a continuous production line of an anti-fingerprint hairline stainless steel plate sequentially comprises an uncoiling mechanism, a leveling mechanism, a bottom polishing mechanism, a wet-grinding wire drawing mechanism, a cleaning and drying mechanism, an anti-fingerprint coating roller coating mechanism, a coating heating mechanism, a cooling mechanism, a film coating mechanism and an uncoiling and cutting mechanism, wherein the anti-fingerprint coating roller coating mechanism comprises a roller coating section, the anti-fingerprint coating roller coating mechanism further comprises a filling section arranged in front of the roller coating section, the filling section comprises a conveying unit capable of conveying along the x-axis direction, a spraying unit erected above the conveying unit, a scraping plate unit arranged below the spraying unit and coating collecting units arranged on two sides of the scraping plate unit, and the scraping plate unit comprises a coating capable of blocking the coating sprayed on the surface of the steel plate from moving along the conveying direction of the steel plate.

In some embodiments, the spray unit includes a gantry, a spray header installed through the gantry, a spray pump, and a paint pond connected with the spray header pipe, and the squeegee unit includes a squeegee support installed through the gantry, a squeegee installation groove provided at a front end of the squeegee support, and a squeegee provided in the squeegee installation groove, and the width of the squeegee is the same as the width of the steel plate.

In some embodiments, the flights are disposed at an incline and at an acute angle to the conveying plane of the conveying unit.

In some embodiments, the bottom of the blade has a wedge surface, and at least the bottom of the blade is made of an elastic material capable of deforming.

In some embodiments, the bottom surface of the wedge-shaped surface is at an obtuse angle to the conveying plane of the conveying unit in a natural state.

In some embodiments, the paint collection unit includes a square tube with a lower end leading to a paint pond, the upper end of the square tube having an opening toward a side wall of the delivery unit, the opening extending into the square tube to form a guide slope.

In some embodiments, a vibration section is further provided between the filling section and the roll coating section, and the vibration section can enable the steel plate to displace upwards and downwards.

In some embodiments, the vibration section comprises a vibration unit, the vibration unit comprises a vibration section frame and a vacuum cavity installed through the vibration section frame, the vacuum cavity is arranged along the y-axis direction, the top surface of the vacuum cavity is lower than the conveying plane of the conveying unit, the top surface of the vacuum cavity is provided with a plurality of vacuum adsorption ports, and the bottom surface of the vacuum cavity is provided with a connecting port connected with a vacuum source.

In some embodiments, the top surface of the vacuum chamber is 3-5mm lower than the transport plane of the transport unit.

In some embodiments, the shock section further comprises a front compression unit located before the shock unit, and a rear compression unit located after the shock unit.

According to the technical scheme of the utility model, the continuous production line of the fingerprint-resistant hairline stainless steel plate has the following advantages: the continuous production line of the anti-fingerprint hairline stainless steel plate can be suitable for coating the anti-fingerprint paint on the surface of the stainless steel plate with deeper wire drawing depth, is a continuous coating mode, and has relatively high production efficiency; at the same time, the deeper hairline is filled with the coating and the air in the hairline is completely exhausted, so the effective period of the protective action of the anti-fingerprint coating on the hairline stainless steel plate can be prolonged.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained from these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a schematic equipment layout of a continuous production line of an anti-fingerprint hairline stainless steel plate according to example 1 of the present utility model.

Fig. 2 is a schematic structural diagram of a filling section according to embodiment 1 of the present utility model.

Fig. 3 is a schematic view showing the structure of a paint collecting unit according to embodiment 1 of the present utility model.

Fig. 4 is a schematic structural diagram of a filling section according to embodiment 2 of the present utility model.

Fig. 5 is a schematic view showing the structure of a squeegee according to embodiment 2 of the utility model.

Fig. 6 is a schematic structural diagram of a vibration section according to embodiment 3 of the present utility model.

Fig. 7 is a schematic structural diagram of a vibration unit according to embodiment 3 of the present utility model.

In the figure: 1. uncoiling mechanism, 2, leveling mechanism, 3, bottom polishing mechanism, 4, wet grinding wire drawing mechanism, 5, cleaning and drying mechanism, 6, fingerprint resistant coating roller coating mechanism, 7, coating heating mechanism, 8, cooling mechanism, 9, film coating mechanism, 10, opening and cutting mechanism, 11, steel plate, 61, filling section, 62, roller coating section, 63, vibration section, 611, conveying rack, 612, conveying unit, 613, portal frame, 614, spray header, 615, screw servo mechanism, 616, scraping plate unit, 617, coating collecting unit, 618, coating pool, 631, vibration unit, 632, front pressing unit, 633, rear pressing unit, 6161, scraping plate bracket, 6162, scraping plate mounting groove, 6163, scraping plate, 6164, tail, 6311, vacuum cavity, 6312, vacuum adsorption port, 6313, connecting port, 6321, front roller conveyor, 6322, front mounting plate, 6323, front pressing roller, 6331, rear roller conveyor, 6332, rear mounting plate, 6333, rear pressing roller.

Detailed Description

In order to make the technical solution of the present utility model better understood by those skilled in the art, the technical solution of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments of the present utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, shall fall within the scope of the utility model.

Example 1

Referring to a continuous production line of the fingerprint-resistant hairline stainless steel plate shown in fig. 1, the continuous production line sequentially comprises an uncoiling mechanism 1, a leveling mechanism 2, a bottom polishing mechanism 3, a wet-grinding wire drawing mechanism 4, a cleaning and drying mechanism 5, a fingerprint-resistant coating roller coating mechanism 6, a coating heating mechanism 7, a cooling mechanism 8, a coating mechanism 9, a flattening and cutting mechanism 10 and a control system. The uncoiling mechanism 1, the leveling mechanism 2, the bottom polishing mechanism 3, the wet grinding wire drawing mechanism 4, the cleaning and drying mechanism 5, the cooling mechanism 8, the film covering mechanism 9 and the opening, leveling and cutting mechanism 10 are all devices in the prior art, for example, the technical schemes described in the utility model patent with publication number CN107776947B and the utility model patent with publication number CN 210818955U; the control system is a PLC control cabinet in the prior art.

The anti-fingerprint coating roll coating mechanism 6 includes a fill section 61 and a roll coating section 62. The roll coating section 62 may be in any form known in the art, such as the one described in the patent publication CN 107776947B.

Referring to fig. 2, the filling section 61 includes a conveying frame 611, a conveying unit 612 capable of conveying in the x-axis direction, a spray unit erected above the conveying unit, a squeegee unit 616 provided below the spray unit, and paint collecting units 617 provided on both sides of the squeegee unit 616.

Specifically, the conveying frame 611 is a frame of the related art, and the conveying unit 612 is a roller conveyor. The steel sheet 11 is conveyed while being placed on a conveying plane of the conveying unit 612.

The spray unit includes a gantry 613, a spray header 614, a spray pump, and a paint reservoir 618. The gantry 613 is installed above the conveying unit 612 and is disposed in the y-axis direction. The shower head 614 is conventional, and may be of the suspension cup type or the atomizing type as long as it can spray or shower the paint. The shower head 614 is mounted on the top surface of the gantry 613 by a screw servo 615 and is reciprocally movable in the y-axis direction by the screw servo 615. The showerhead 614 is connected to a paint reservoir 618 via piping (not shown), a spray pump. The control system can control the spray pump to turn on so that the spray header 614 can spray paint, and control the screw servo 615 to drive the spray header 614 to reciprocate along the y-axis direction to complete the coating of the entire width of the steel plate 11.

The squeegee unit 616 includes a member capable of blocking paint sprayed on the surface of the steel sheet 11 from moving in the conveying direction with the steel sheet 11. As shown in connection with fig. 3, the squeegee unit 616 includes a squeegee support 6161 mounted by a portal frame 613, a squeegee mounting groove 6162 provided at a front end of the squeegee support 6161, and a squeegee 6163 provided at the squeegee mounting groove 6162, the width of the squeegee 6163 is the same as that of the steel plate, and when the steel plate 11 passes the squeegee 6163, a bottom portion of the squeegee 6163 can contact the surface of the steel plate 11. By providing the scraper 6163, it is possible to deposit paint at the lower end of the rear side (the side facing the conveying direction is the front side, and the side opposite to the conveying direction is the rear side), and the deposited paint is facilitated to enter the hairline on the surface of the steel sheet 11. Further, the scraping plate 6163 can also promote the paint to enter the hairline on the surface of the steel plate 11 through a knife coating mode, so that the continuous production line of the anti-fingerprint hairline stainless steel plate of the embodiment can be suitable for coating the anti-fingerprint paint on the surface of the stainless steel plate with deeper wire drawing depth, and has relatively high production efficiency due to a continuous coating mode. At the same time, the deeper hairline is filled with the coating, and the air in the hairline is completely discharged, so that the effective period of the protective action of the anti-fingerprint coating on the hairline stainless steel plate can be prolonged.

The paint collecting units 617 are located at both sides of the blade unit 616 for guiding the paint deposited on the rear side of the blade 6163 to flow back to the paint reservoir 618, so as to achieve recycling of the paint and to avoid excessive deposition of the paint on the rear side of the blade 6163. As shown in fig. 4, the paint collecting unit 617 includes a square pipe 6171 having a lower end leading to the paint reservoir 618, and a side wall of the square pipe 6171 facing the conveying unit 612 at an upper end thereof has an opening 6172, and the opening 6172 extends into the square pipe 6171 to form a guide slope 6173.

Example 2

Referring to fig. 5, embodiment 2 differs from embodiment 1 in that the scraper 6163 is disposed obliquely and at an acute angle α to the conveying plane of the conveying unit 612, which is preferably 10 to 15 °. The presence of the angle α can promote build-up of coating on the rear side of the blade 6163, but it should not be greater than 15 ° to avoid excessive build-up of coating on the rear side of the blade 6163.

As a preferred embodiment, the bottom of the blade 6163 has a wedge-shaped surface, and at least the bottom of the blade 6163 is made of an elastic material capable of being deformed. In this embodiment, the bottom of the scraper 6163 has a wedge-shaped surface, the bottom surface of which is at an obtuse angle β with respect to the conveying plane of the conveying unit 612 in a natural state (i.e., in the case where no steel plate 11 passes through the scraper unit 616), and the angle β is preferably 165 to 170 °. The blade 6163 of the present embodiment is made of an elastic resin so that the bottom of the blade 6163 forms a plane and one tail 6164 when the steel plate 11 passes through the blade unit 616, as in the broken line structure in fig. 5. The presence of this tail 6164 can further facilitate the extrusion of coating material onto the hairline.

Example 3

Referring to fig. 6, embodiment 3 is different from embodiment 1 or embodiment 2 in that a vibration section 63 is further provided between the filling section 61 and the roll coating section 62, and the vibration section 63 is capable of displacing the steel plate 11 upward and downward.

Specifically, as shown in fig. 7, the vibration section 63 includes a vibration unit 631, the vibration unit 631 includes a vibration section frame, a vacuum chamber 6311 mounted through the vibration section frame, the vacuum chamber 6311 is disposed along the y-axis direction, a top surface of the vacuum chamber 6311 is lower than a conveying plane of the conveying unit 612, a top surface of the vacuum chamber 6311 has a plurality of vacuum suction ports 6312, and a bottom surface of the vacuum chamber has a connection port 6313 connected with a vacuum source (not shown in the drawing). The top surface of the vacuum chamber 6311 is 3-5mm (e.g., 3.5 mm) lower than the conveying plane of the conveying unit 612. The control system can control the vacuum source to cause the vacuum suction port 6312 to vacuum-suck the steel plate 11 passing through the vibration section 63, stop the vacuum suction after a period of time, for example, 0.5-1s, and again vacuum-suck again after a period of time, for example, 0.5-1 s. The above-described operation is repeated so that the steel plate 11 passing through the vibration section 63 is vibrated, and the paint is caused to flow into the hairline by the vibration.

Referring back to fig. 6, as a preferred embodiment, the vibration section 63 further includes a front pressing unit 632 located before the vibration unit 631, and a rear pressing unit 633 located after the vibration unit 631. The front pressing unit 632 and the rear pressing unit 633 have the same structure. The front pressing unit 632 includes a front roller conveyor 6321, a pair of front mounting plates 6322 screwed or welded to both sides of a rear end (a front end on a side facing the conveying direction and a rear end on a side opposite to the conveying direction) of a frame provided on the front roller conveyor 6321, and a plurality of front pressing rollers 6323 mounted on the front mounting plates 6322 through bearings. The rear pressing unit 633 includes a rear roller conveyor 6331, a pair of rear mounting plates 6332 screw-coupled or welded to both sides of a rear end of a frame of the rear roller conveyor 6331, and a plurality of rear pressing rollers 6333 mounted on the rear mounting plates 6332 through bearings.

Preferably, the front and rear pinch rollers 6323, 6333 are short rollers, so that the front and rear pinch rollers 6323, 6333 are only pinched at the side edges of the steel plate 11, which will be cut out in the opening and cutting mechanism 10. Therefore, the lengths of the front and rear pinch rollers 6323, 6333 should be smaller than the width to be cut.

More preferably, the compacting length (x-axis direction) of the plurality of front compacting rollers 6323 is about half the length of the front roller conveyor 6321; the pinch length of the plurality of rear pinch rollers 6333 is approximately half the length of the rear roller conveyor 6331.

The foregoing description is for purposes of illustration and is not intended to be limiting. Many embodiments and many applications other than the examples provided will be apparent to those of skill in the art upon reading the above description. The scope of the present teachings should, therefore, be determined not with reference to the above description, but instead should be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. The disclosures of all articles and references, including patent applications and publications, are incorporated herein by reference for the purpose of completeness. The omission of any aspect of the subject matter disclosed herein in the preceding claims is not intended to forego such subject matter, nor should the applicant be deemed to have such subject matter not considered to be part of the subject matter of the disclosed application.

Claims (10)

1. The utility model provides a continuous production line of anti fingerprint hairline corrosion resistant plate, includes uncoiling mechanism, leveling mechanism, end throwing mechanism, wet milling wire drawing mechanism, washs stoving mechanism, anti fingerprint coating roller coat mechanism, coating heating mechanism, cooling body, tectorial membrane mechanism, opens flat and cutting mechanism in proper order, anti fingerprint coating roller coat mechanism includes the roller coat section, its characterized in that, anti fingerprint coating roller coat mechanism still including set up in the section of filling before the roller coat section, the section of filling including can follow the conveying unit that x axis direction was carried, erect spray unit in the conveying unit top, set up in the scraper unit of spray unit below and set up in the coating collecting unit of scraper unit both sides, the scraper unit including can block the coating that sprays on the steel sheet surface along with the steel sheet removes along the conveying direction.

2. The continuous production line of an anti-fingerprint hairline stainless steel plate according to claim 1, wherein the spray unit comprises a portal frame, a spray head installed through the portal frame, a spray pump, and a paint pond connected with the spray head pipeline, the scraper unit comprises a scraper bracket installed through the portal frame, a scraper installation groove provided at the front end of the scraper bracket, and a scraper provided at the scraper installation groove, and the width of the scraper is the same as the width of the steel plate.

3. The continuous production line of anti-fingerprint hairline stainless steel plate according to claim 2, wherein the scraper is obliquely disposed and forms an acute angle with the conveying plane of the conveying unit.

4. The continuous production line of anti-fingerprint hairline stainless steel plate as claimed in claim 2, wherein the bottom of the scraper has a wedge surface, and at least the bottom of the scraper is made of an elastic material capable of being deformed.

5. The continuous production line of anti-fingerprint hairline stainless steel plate according to claim 4, wherein the bottom surface of the wedge-shaped surface is at an obtuse angle with respect to the conveying plane of the conveying unit in a natural state.

6. The continuous production line of anti-fingerprint hairline stainless steel plates according to claim 1, wherein the paint collecting unit comprises a square tube having a lower end leading to a paint pool, an upper end of the square tube having an opening toward a side wall of the conveying unit, the opening extending into the square tube to form a guide slope.

7. The continuous production line of anti-fingerprint hairline stainless steel plates according to claim 1, wherein a vibration section is further provided between the filling section and the roll coating section, and the vibration section enables the steel plates to be displaced upwards and downwards.

8. The continuous production line of anti-fingerprint hairline stainless steel plates according to claim 7, wherein the vibration section comprises a vibration unit, the vibration unit comprises a vibration section frame and a vacuum cavity installed through the vibration section frame, the vacuum cavity is arranged along the y-axis direction, the top surface of the vacuum cavity is lower than the conveying plane of the conveying unit, the top surface of the vacuum cavity is provided with a plurality of vacuum adsorption ports, and the bottom surface of the vacuum cavity is provided with a connecting port connected with a vacuum source.

9. The continuous production line of anti-fingerprint hairline stainless steel plate according to claim 8, wherein the top surface of the vacuum chamber is 3-5mm lower than the conveying plane of the conveying unit.

10. The continuous production line of anti-fingerprint hairline stainless steel sheet according to claim 8, wherein said vibration section further comprises a front pressing unit located before said vibration unit and a rear pressing unit located after said vibration unit.