Glass fiber film material surface coating compound equipment

By designing the spraying mechanism, non-contact spraying is achieved through the reciprocating motion of the slider and pump body, which solves the problem of damage to the membrane material caused by the brush-like structure and improves the service life and aesthetics of the membrane material.

CN224332456UActive Publication Date: 2026-06-09JIANGSU VEIK TECH & MATERIALS CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGSU VEIK TECH & MATERIALS CO LTD
Filing Date
2025-06-10
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

The brush-like structure of existing coating compounding devices can easily damage the membrane material, affecting its service life and aesthetics.

Method used

The coating mechanism uses a lead screw in the horizontal box to drive the slider to reciprocate, and sprays the coating onto the film material through the pump body and one-way flow pipes to avoid contact damage.

Benefits of technology

It improves the service life and aesthetics of the membrane material, and achieves damage-free spraying.

✦ Generated by Eureka AI based on patent content.

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    Figure CN224332456U_ABST
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Abstract

The utility model provides a kind of glass fibre membrane material surface coating compound equipment, it is related to building membrane material technical field, including pedestal plate and spraying mechanism, the side upper portion of pedestal plate is provided with the bolt assembly of material conveying component, the other side upper portion of pedestal plate is provided with the bolt assembly of mixing component;The utility model mainly is using the transverse box of being installed in the inside upper portion of mixing component, the driving of screw in transverse box can be played to sliding block, realize reciprocating operation effect for sliding block, in reciprocating operation, the paint mixed in mixing component can be extracted using the pump body on the plug-in seat, using the pipe fitting of one-way flow is finally sprayed on the membrane material in straight state by lower bracing rod and upper bracing rod, to complete the effect of spraying, so the spraying effect of spraying mechanism is not contacted, thus, will not cause damage to membrane material, both improve service life and guarantee the aesthetic effect.
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Description

Technical Field

[0001] This utility model relates to the field of architectural membrane technology, and in particular to a coating compounding device for fiberglass membrane surface. Background Technology

[0002] Fiberglass sheets are products made by pre-impregnating glass fiber yarn with styrene-based polyester resin and then pultruding it through heating and curing. Fiberglass sheets have good toughness, high strength, low density, excellent corrosion resistance and heat resistance, good formability, and long shelf life. They are low-energy-consumption, environmentally friendly materials with no pollution. Fiberglass sheets are often coated with different coatings to form films according to requirements. There are various ways to make coatings, such as pressing, coating, rolling, engraving roller, and roller coating.

[0003] Existing high-efficiency coating compounding devices typically utilize a solid bristle structure, such as a rolling brush, to apply coating to the membrane material to achieve the coating effect. However, the bristle structure is also similar to a solid state. Although the brush-like coating structure has a certain degree of elasticity, it can still cause some damage to the membrane material, which is detrimental to the long-term use of the membrane material and also affects its aesthetic appearance. Therefore, this utility model proposes a surface coating compounding device for fiberglass membrane materials to solve the problems existing in the prior art. Utility Model Content

[0004] To address the aforementioned problems, this utility model proposes a fiberglass membrane surface coating compounding device. This high-efficiency compounding device for architectural membrane surface coatings mainly utilizes a horizontal box installed above the inner side of the mixing component. A lead screw within the horizontal box drives a slider, enabling the slider to reciprocate. During this reciprocating motion, a pump on the connector draws the mixed coating from the mixing component and sprays it onto the membrane material, which is taut by the lower and upper tension rods, through a one-way flow pipe. This completes the coating process. Since the coating is non-contact, it does not damage the membrane material, thus extending its service life and ensuring an aesthetically pleasing result.

[0005] To achieve the purpose of this utility model, the utility model is implemented through the following technical solution: a glass fiber membrane surface coating compounding device, including a base plate and a spraying mechanism, wherein a bolt-assembled material conveying assembly is provided on the upper side of one side of the base plate, a bolt-assembled mixing component is provided on the upper side of the other side of the base plate, and a spraying mechanism is provided on the upper side of the inner edge of the mixing component.

[0006] The spraying mechanism includes a side frame, a horizontal box, an electric screw, a slider, a connector, a pump body, a drive motor, an extraction tube, and a nozzle. The side frame is located above the inner side of the mixing component. A horizontal box is located on one side of the top of the side frame. A slider is threaded onto the horizontal box via an electric screw. One end of the slider is inserted into a connector, and a pump body connected to the output end of the drive motor is located on the top side of the connector. The pump body is connected to the mixing component via an extraction tube, and a nozzle is located on the other side of the pump body.

[0007] As a further technical solution, the pump body, the extraction pipe and the nozzle form a unidirectional flow structure, and the nozzle has an array of holes.

[0008] As a further technical solution, the feeding assembly includes an upper push rod, a film output roll, a clamping cylinder, a side strip seat, a first smoothing rod, a lower tension rod, an upper tension rod, a second smoothing rod, an upper shaft seat, a take-up roll, a take-up motor, a top seat, a wind hood, and a fan. The lower inner side of the upper push rod is provided with a film output roll connected to the output end of the clamping cylinder. A side strip seat is provided on one side of the upper push rod, and the inner end of the side strip seat is provided with a first smoothing rod and a second smoothing rod that are parallel to each other. The outer end of the side strip seat is provided with a lower tension rod and an upper tension rod that are parallel to each other.

[0009] As a further technical solution, an upper shaft seat is provided on the inner side of the top end of the upper rod, and a take-up drum connected to the output end of the take-up motor is provided on the inner side of the upper shaft seat.

[0010] As a further technical solution, a bolt-fitted top seat is provided on the outer side of the top end of the upper rod, and a fan cover for mounting the fan is provided on the top seat.

[0011] As a further technical solution, the mixing component includes a bolt base, a mixing barrel, a top cover, a second motor, and a stirring rod. The bolt base is located above the other side of the base plate, and the mixing barrel is located above the rear side of the bolt base. A top cover is located on the top side of the mixing barrel, and a second motor is located on the top side of the top cover. The output end of the second motor passes through the top cover and is connected to the stirring rod.

[0012] The beneficial effects of this utility model are as follows:

[0013] This invention mainly utilizes a horizontal box installed on the upper inner side of the mixing component. A lead screw in the horizontal box drives a slider, enabling the slider to reciprocate. During this reciprocating motion, a pump on the connector draws the mixed coating material from the mixing component and sprays it onto the taut membrane material held in place by the lower and upper tension rods through a one-way flow pipe. This completes the spraying effect. Since the spraying mechanism operates without contact, it does not damage the membrane material, thus extending its service life and ensuring an aesthetically pleasing result. Attached Figure Description

[0014] Figure 1 This is a three-dimensional structural diagram of the present invention;

[0015] Figure 2 This is a side view of the three-dimensional structure of the present invention;

[0016] Figure 3 This is a three-dimensional structural diagram of the fan cover and fan of this utility model;

[0017] Figure 4 This is a cross-sectional three-dimensional structural diagram of the hybrid component of this utility model;

[0018] Figure 5 This is a three-dimensional structural diagram of the spraying mechanism of this utility model.

[0019] The components include: 1. Base plate; 2. Material conveying assembly; 201. Upper push rod; 202. Film output roll; 203. Clamping cylinder; 204. Side strip seat; 205. First smoothing rod; 206. Lower tension rod; 207. Upper tension rod; 208. Second smoothing rod; 209. Upper shaft seat; 2010. Take-up roll; 2011. Take-up motor; 2012. Top seat; 2013. Air hood; 2014. Fan; 3. Mixing component; 301. Bolt base; 302. Mixing tank; 303. Top cover; 304. Second motor; 305. Stirring rod; 4. Spraying mechanism; 401. Side frame; 402. Horizontal box; 403. Electric lead screw; 404. Slider; 405. Plug-in seat; 406. Pump body; 407. Drive motor; 408. Extraction pipe; 409. Nozzle. Detailed Implementation

[0020] To deepen the understanding of this utility model, the following detailed description will be provided in conjunction with embodiments. These embodiments are only used to explain this utility model and do not constitute a limitation on the scope of protection of this utility model.

[0021] according to Figure 1-5As shown, this embodiment proposes a glass fiber membrane surface coating compounding device, including a base plate 1 and a spraying mechanism 4. A bolt-assembled material conveying assembly 2 is provided on one side of the base plate 1, and a bolt-assembled mixing component 3 is provided on the other side of the base plate 1. The spraying mechanism 4 is provided on the inner side of the mixing component 3.

[0022] The spraying mechanism 4 includes a side frame 401, a horizontal box 402, an electric screw 403, a slider 404, a connector 405, a pump body 406, a drive motor 407, an extraction tube 408, and a nozzle 409. The side frame 401 is located above the inner side of the mixing component 3. A horizontal box 402 is located on one side of the top of the side frame 401. A slider 404 is threaded onto the horizontal box 402 via an electric screw 403. One end of the slider 404 is inserted into a connector 405. A pump body 406 connected to the output end of the drive motor 407 is located on the top side of the connector 405. The pump body 406 is connected to the mixing component 3 via an extraction tube 408. A nozzle 409 is located on the other side of the pump body 406.

[0023] The pump body 406, the extraction pipe 408, and the nozzle 409 form a unidirectional flow structure, and the nozzle 409 has an array of holes.

[0024] In this embodiment, after the mixing component 3 is filled with spray paint, the electric lead screw 403 on the horizontal box 402 is activated to output power and drive the slider 404 to reciprocate. Under this trajectory, the drive motor 407 is activated to output power and drive the output end of the drive motor 407 to run. In this way, the output end of the drive motor 407 drives the pump body 406 to use the extraction pipe 408 to extract the spray paint in the mixing tank 302. Finally, the spray paint is sprayed onto the membrane material between the lower tension rod 206 and the upper tension rod 207 through the nozzle 409 on one side of the pump body 406, thus achieving the spraying effect.

[0025] The feeding assembly 2 includes an upper push rod 201, a film output roll 202, a clamping cylinder 203, a side strip seat 204, a first smoothing rod 205, a lower tension rod 206, an upper tension rod 207, a second smoothing rod 208, an upper shaft seat 209, a take-up roll 2010, a take-up motor 2011, a top seat 2012, a wind hood 2013, and a fan 2014. The film output roll 202, which is connected to the output end of the clamping cylinder 203, is provided on the inner side of the lower part of the upper push rod 201. The side strip seat 204 is provided on one side of the upper push rod 201, and the first smoothing rod 205 and the second smoothing rod 208, which are parallel to each other, are provided on the inner end of the side strip seat 204. The lower tension rod 206 and the upper tension rod 207, which are parallel to each other, are provided on the outer end of the side strip seat 204.

[0026] In this embodiment, the required film material is output by using the film output roll 202. The film material output by the film output roll 202 runs to the first smoothing rod 205, passes through the lower tension rod 206 and is wound to the upper tension rod 207 to achieve straightening. Then, through the straightening of the upper tension rod 207, it runs to the second smoothing rod 208 and is wound to the take-up roll 2010.

[0027] An upper shaft seat 209 is provided on the inner side of the top end of the upper push rod 201, and a take-up drum 2010 connected to the output end of the take-up motor 2011 is provided on the inner side of the upper shaft seat 209.

[0028] In this embodiment, after the film material is wound onto the take-up roll 2010, the take-up motor 2011 is started to output power to drive the output end of the take-up motor 2011 to run, so that the output end of the take-up motor 2011 drives the take-up roll 2010 inside the upper shaft seat 209 to run, so as to achieve the effect of slow take-up.

[0029] The top of the top rod 201 is provided with a bolt-fitted top seat 2012, and the top seat 2012 is provided with a fan cover 2013 for mounting the fan 2014.

[0030] In this embodiment, after the spraying operation is completed, the fan 2014, which acts as the inner side of the hood 2013, outputs air force to dry the coating material between the second smoothing rod 208 and the take-up drum 2010. After drying, the coating material is wound around by the take-up drum 2010 in conjunction with the take-up motor 2011.

[0031] The mixing component 3 includes a bolt base 301, a mixing tank 302, a top cover 303, a second motor 304, and a stirring rod 305. The bolt base 301 is located on the other side of the base plate 1. The mixing tank 302 is located on the rear side of the bolt base 301. The top cover 303 is located on the top side of the mixing tank 302. The second motor 304 is located on the top side of the top cover 303. The output end of the second motor 304 passes through the top cover 303 and is connected to the stirring rod 305.

[0032] In this embodiment, during slow material collection, the spray coating is placed into the mixing tank 302, and the second motor 304 is started to output power to drive the output end of the second motor 304 to run, so that the output end of the second motor 304 drives the stirring rod 305 under the top cover 303 to rotate, thereby achieving a thorough stirring effect on the raw materials in the mixing tank 302.

[0033] The working principle of this high-efficiency compounding device for architectural membrane surface coating is as follows: First, the required membrane material is output using the membrane output drum 202. The membrane material output from the membrane output drum 202 travels to the first smoothing rod 205, passes through the lower tensioning rod 206, and is wound onto the upper tensioning rod 207 to achieve tautness. Then, it travels to the second smoothing rod 208 after being taut by the upper tensioning rod 207 and is wound onto the take-up drum 2010. After the membrane material is wound onto the take-up drum 2010, the take-up motor 2011 is started to output power and drive the output end of the take-up motor 2011 to run. This causes the output end of the take-up motor 2011 to drive the take-up drum 2010 inside the upper shaft seat 209 to achieve a slow take-up effect. During slow take-up, the spray coating material is placed into the mixing tank 302, and the second motor 304 is started to output power and drive the output end of the second motor 304 to run. This causes the output end of the second motor 304 to drive the stirring rod 305 below the top cover 303 to enter the mixing tank 302. The rotating mechanism ensures thorough mixing of the raw materials in the mixing tank 302. After the mixing component 3 is filled with spray paint, the electric screw 403 on the horizontal box 402 is activated to drive the slider 404 to reciprocate. This movement of the slider 404 in this trajectory activates the drive motor 407, which in turn drives the pump body 406 to extract the spray paint from the mixing tank 302 through the extraction pipe 408. The paint is then sprayed onto the membrane material between the lower tension rod 206 and the upper tension rod 207 through the nozzle 409 on one side of the pump body 406. After the spraying operation is completed, the fan 2014 inside the hood 2013 outputs airflow to dry the coating material between the second smoothing rod 208 and the take-up drum 2010. The dried membrane material is then wound around the take-up drum 2010 by the take-up motor 2011.

[0034] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed utility model. The scope of protection of this utility model is defined by the appended claims and their equivalents.

Claims

1. A fiberglass membrane surface coating compounding device, comprising a base plate (1) and a spraying mechanism (4), characterized in that: A bolt-assembled material conveying assembly (2) is provided above one side of the base plate (1), and a bolt-assembled mixing component (3) is provided above the other side of the base plate (1), and a spraying mechanism (4) is provided above the inner side of the mixing component (3). The spraying mechanism (4) includes a side frame (401), a horizontal box (402), an electric screw (403), a slider (404), a connector (405), a pump body (406), a drive motor (407), an extraction tube (408), and a nozzle (409). The side frame (401) is located above the inner side of the mixing component (3). A horizontal box (402) is provided on one side of the top of the side frame (401). A slider (404) is threadedly connected to the horizontal box (402) via an electric screw (403). One end of the slider (404) is connected to a connector (405), and a pump body (406) connected to the output end of the drive motor (407) is provided on the top side of the connector (405). The pump body (406) is connected to the mixing component (3) via an extraction tube (408), and a nozzle (409) is provided on the other side of the pump body (406).

2. The fiberglass membrane surface coating compounding equipment according to claim 1, characterized in that: The pump body (406), the extraction pipe (408), and the nozzle (409) form a unidirectional flow structure, and the nozzle (409) has an array of holes.

3. The fiberglass membrane surface coating compounding equipment according to claim 1, characterized in that: The feeding assembly (2) includes an upper push rod (201), a film output drum (202), a clamping cylinder (203), a side strip seat (204), a first smoothing rod (205), a lower tensioning rod (206), an upper tensioning rod (207), a second smoothing rod (208), an upper shaft seat (209), a take-up drum (2010), a take-up motor (2011), a top seat (2012), a fan shroud (2013), and a fan (2014). The inner side below the top rod (201) is provided with a film roll (202) that connects to the output end of the clamping cylinder (203). A side strip seat (204) is provided on one side of the top rod (201), and a first smoothing rod (205) and a second smoothing rod (208) that are parallel to each other are provided on the inner end side of the side strip seat (204). A lower tension rod (206) and an upper tension rod (207) that are parallel to each other are provided on the outer end side of the side strip seat (204).

4. The fiberglass membrane surface coating compounding equipment according to claim 3, characterized in that: The top of the upper rod (201) is provided with an upper shaft seat (209) on the inner side, and the upper shaft seat (209) is provided with a take-up drum (2010) connected to the output end of the take-up motor (2011) on the inner side.

5. The fiberglass membrane surface coating compounding equipment according to claim 3, characterized in that: The top of the upper rod (201) is provided with a bolt-fitted top seat (2012) on the outer side, and a fan cover (2013) for mounting a fan (2014) is provided on the top seat (2012).

6. The fiberglass membrane surface coating compounding equipment according to claim 1, characterized in that: The mixing component (3) includes a bolt base (301), a mixing barrel (302), a top cover (303), a second motor (304), and a stirring rod (305). The bolt base (301) is located above the other side of the base plate (1). The mixing barrel (302) is located above the rear side of the bolt base (301), and the top cover (303) is located on the top side of the mixing barrel (302). The second motor (304) is located on the top side of the top cover (303), and the output end of the second motor (304) is connected to the stirring rod (305) through the top cover (303).