CN115446011A

CN115446011A - Glass mold cleaning device

Info

Publication number: CN115446011A
Application number: CN202211027429.0A
Authority: CN
Inventors: 戈剑鸣
Original assignee: Ori Mould Technology Suzhou Co ltd
Current assignee: Ori Mould Technology Suzhou Co ltd
Priority date: 2022-08-25
Filing date: 2022-08-25
Publication date: 2022-12-09
Anticipated expiration: 2042-08-25
Also published as: CN115446011B

Abstract

The invention relates to a glass mold cleaning device, which comprises: a cleaning tank, a water tank and a circulating pump; the conveying belt is arranged at the downstream of the cleaning tank, a closed metal plate cover is wrapped at the periphery of the cleaning tank, air nozzles distributed along the extension direction of the conveying belt are arranged in the metal plate cover, and a steam fog recovery mechanism is arranged at the tail end of the metal plate cover; and a robot configured to convey the glass mold between the cleaning bath and a starting end of the conveyor. Also provided is a glass mold cleaning method comprising: s1, soaking a glass mold by using a cleaning tank, circulating cleaning liquid between the cleaning tank and a water tank by using a circulating pump, and filtering impurities in the cleaning liquid by using a filter screen; s2, conveying the glass mold on a conveyor belt, and spraying compressed gas to blow and sweep the glass mold in the conveying process; s3, absorbing flying dust through a vapor recovery mechanism. Soaking the glass mold in the cleaning solution to primarily remove oil stains and impurities on the surface of the glass mold, and then blowing high-pressure gas in a closed environment to further clean the glass mold.

Description

Glass mold cleaning device

Technical Field

The invention belongs to the field of glass mold manufacturing, and relates to a glass mold cleaning device.

Background

Glass bottle manufacture requires the use of glass molds. In the production of a glass mold, the surface of the glass mold is contaminated with a cutting fluid, stains, and the like, and therefore, it is necessary to clean the surface. The removal of the surface deposits on the glass mold is generally performed by a spraying method disclosed in "CN211160943U" (a glass mold oil washing apparatus), "CN211217744U" (a glass mold oil washing apparatus), and "CN201783479U" (a mold washing apparatus) by spraying a washing liquid onto the surface of the glass mold and recovering the washing liquid. The cleaning effect of the spraying method on the surface of the glass mold needs to be further improved.

Disclosure of Invention

The invention aims to provide a glass mold cleaning device, which solves the problem of improving the surface cleaning effect of a glass mold.

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

the invention provides a glass mold cleaning device, which comprises:

a cleaning tank;

the conveying belt is arranged at the downstream of the cleaning tank, a closed metal plate cover is wrapped at the periphery of the conveying belt, air nozzles distributed along the extension direction of the conveying belt are arranged in the metal plate cover, and a steam fog recovery mechanism is arranged at the tail end of the metal plate cover;

a robot configured to convey a glass mold between the cleaning bath and a starting end of the conveyor;

it still includes water tank and circulating pump, the circulating pump is connected the water tank with between the washing tank. At least one layer of filter screen which is blocked between the liquid inlet and the liquid outlet of the water tank is arranged in the water tank;

the glass mold cleaning device is characterized by further comprising a cleaning frame used for loading the glass mold, the manipulator is configured to be capable of grabbing the cleaning frame, two opposite side walls of the cleaning frame are provided with leaking holes, and the end faces corresponding to the leaking holes are smooth planes.

Preferably, the robot arm includes a pneumatic gripper and a rotating mechanism for rotating the pneumatic gripper.

Preferably, the glass mold cleaning device further comprises an incoming material placing table, wherein a positioning block for positioning the cleaning frame is arranged on the incoming material placing table, and the manipulator is configured to convey the glass mold between the incoming material placing table and the cleaning tank.

Preferably, two opposite side walls of the cleaning frame are provided with leakage holes.

Furthermore, an outward-extending supporting strip is arranged at the top edge of the side wall adjacent to the leak hole, and the supporting strip is used for lifting the manipulator.

Preferably, the conveyer belt discharge end still is provided with infrared inductive sensor, infrared inductive sensor is used for the monitoring material on the conveyer belt.

Also provided is a glass mold cleaning method, comprising:

s1, soaking a glass mold in a cleaning tank loaded with cleaning liquid, loading the glass mold in a cleaning frame, forming leak holes in two opposite side walls of the cleaning frame, wherein the end surfaces corresponding to the leak holes are smooth planes, circulating the cleaning liquid between the cleaning tank and a water tank through a circulating pump, and filtering impurities in the cleaning liquid through at least one layer of filter screen arranged in the water tank;

s2, conveying the glass mold on a conveying belt with a closed metal plate cover surrounding the periphery, and spraying compressed gas to the glass mold for blowing and sweeping through air nozzles distributed in the metal plate cover along the extension direction of the conveying belt in the conveying process;

and S3, absorbing the flying dust in the sheet metal cover through a vapor fog recovery mechanism at the tail end of the sheet metal cover.

Preferably, a washing frame is used to load and transport the glass molds.

Furthermore, two opposite side walls of the cleaning frame are provided with leakage holes for the cleaning liquid and the compressed gas to pass through. Due to the application of the technical scheme, compared with the prior art, the invention has the following advantages:

according to the glass mold cleaning device and the glass mold cleaning method, the glass mold is firstly immersed into the cleaning tank loaded with the cleaning solution, so that the cleaning solution is fully contacted with the surface of the glass mold on one hand, and impurities such as cutting scraps and the like attached to the surface of the glass mold are separated from the glass mold and sink into the cleaning solution on the other hand, then the glass mold is placed on the conveying belt, and the air nozzle is used for blowing the surface of the glass mold in the conveying process of the conveying belt. According to the cleaning method, the glass mold can be fully contacted with the cleaning liquid in the immersing mode to clean surface oil stains, so that a primary cleaning effect is achieved, and the air nozzle can generate a large jet force to further clean and dry the glass mold. Compared with a spraying mode, the cleaning device is a breakthrough improvement and has the beneficial effect of improving the cleaning quality.

Drawings

Some specific embodiments of the invention will be described in detail hereinafter, by way of illustration and not limitation, with reference to the accompanying drawings. The same reference numbers in the drawings identify the same or similar elements or components. Those skilled in the art will appreciate that the drawings are not necessarily drawn to scale. In the drawings:

FIG. 1 is a schematic diagram of the combination of the cleaning tank, conveyor and robot in a preferred embodiment of the present invention;

FIG. 2 is an enlarged view at A in FIG. 1;

FIG. 3 is a schematic view of the combination of the cleaning tank and the water tank;

FIG. 4 is a schematic illustration of the cooperation of the conveyor belt and the sheet metal cover;

wherein the reference numerals are as follows:

1. a cleaning tank;

2. a conveyor belt;

3. a sheet metal cover;

4. an air nozzle;

5. a vapor recovery mechanism;

6. a manipulator; 61. a pneumatic clamping jaw; 62. a rotation mechanism;

7. a glass mold;

8. cleaning the frame; 81. a leak hole; 82. supporting the strip;

9. an incoming material placing table;

10. positioning a block;

11. a water tank;

12. a circulation pump;

13. a filter screen;

14. an infrared induction sensor;

15. a sliding table;

16. a guide rail;

17. a slide plate;

18. a lifting plate;

19. and (4) connecting the pipes.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In addition, the technical features involved in the different embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

As shown in fig. 1, the glass mold cleaning apparatus mainly includes a cleaning tank 1, a conveyor 2, and a robot 6. The glass mold 7 is grabbed into the cleaning tank 1 by the manipulator 6, the glass mold 7 is immersed in the cleaning solution contained in the cleaning tank 1, and various cleaning solutions in the prior art can be used as the cleaning solution. The robot 6 then picks up the glass mold 7 on the conveyor 2 and transports it to a remote place. As shown in fig. 4, during the conveyance of the glass mold 7 on the conveyor 2, the glass mold 7 is further cleaned and dried by blowing the glass mold 7 by the air nozzle 4. The details are as follows.

As shown in fig. 1 and 2, a supplied material placing table 9 is provided outside the cleaning tank 1, and the robot arm 6 picks up the glass mold 7 on the supplied material placing table 9. The glass mold 7 is loaded in the cleaning frame 8 and placed on the incoming material placing table 9 by the operator. And a positioning block 10 is arranged on the incoming material placing table 9, and the positioning block 10 is provided with a right-angle groove for positioning the position of the cleaning frame 8. And the number of the positioning blocks 10 can also be two, and the positioning blocks are distributed on two sides of the incoming material placing platform 9. After the position of the cleaning frame 8 is well positioned, the manipulator 6 can conveniently and accurately grab the cleaning frame. The glass mold 7 is placed in the cleaning frame 8, so that the glass mold 7 is convenient to carry.

As shown in fig. 2, in this embodiment, the left and right sides of the top edge of the cleaning frame 8 are provided with outward extending support bars 82, and the support bars 82 penetrate the entire length of the top edge of one side. And the top edges of the other two sides are not provided with the supporting strips 82, the side walls of the corresponding end parts of the cleaning frame 8 without the supporting strips 82 are provided with four leakage holes 81, and the areas occupied by the leakage holes 81 are large enough to almost occupy the whole end surface. The number and shape of the weep holes 81 are not particularly limited. The weep holes 81 facilitate the flow of cleaning liquid into the cleaning frame 8, and the weep holes 81 also facilitate the purging of the glass mold 7 by the air nozzles 4 (see fig. 4). And the top edge of the end face corresponding to the drain hole 81 is not provided with the support strip 82, that is, the end face corresponding to the drain hole 81 is a smooth plane, and the support strip 82 is not provided, so that the air injection of the air nozzle 4 is not blocked (the air nozzle 4 may blow into the drain hole 81 from the upper side obliquely downwards), thereby improving the blowing effect of the air nozzle 4.

As shown in fig. 1, the robot 6 is connected to a lift plate 18, the lift plate 18 is liftably connected to a slide plate 17, the slide plate 17 is fitted to a guide rail 16 and can slide along the guide rail 16, and the guide rail 16 extends laterally on the slide table 15. The guide rails 16 are provided with two parallel guide rails, the guide rails 16 are distributed in the up-down direction on the side surfaces of the sliding table 15, and the two guide rails 16 enable the manipulator 6 to be more stable than one guide rail 16. The sliding table 15 and the guide rail 16 cover a part of the length of the incoming material placing table 9, the wash bowl 1, and the start end of the conveyor belt 2, so that the robot arm 6 can grasp and transfer the wash frame 8 among the incoming material placing table 9, the wash bowl 1, and the conveyor belt 2.

The robot 6 includes a pneumatic gripper 61 and a rotating mechanism 62. The pneumatic gripper 61 is able to grip and hold the carrier strip 82 and thus lift the wash frame 8. The rotating mechanism 62 rotates the pneumatic chuck 61 using a rotating cylinder. In this example, when the cleaning frame 8 is grabbed from the cleaning tank 1 onto the conveyor 2, the cleaning frame 8 is rotated by 90 ° so that the orifices 81 of the cleaning frame 8 are located at both sides (both sides with respect to the conveying direction of the conveyor 2), thereby facilitating the blowing of the high-pressure gas from the gas nozzles 4 (see fig. 4) through the orifices 81 toward the glass mold 7.

The cleaning frame 8 is filled with a cleaning liquid. After the cleaning frame 8 is placed in the cleaning tank 1 by the manipulator 6, the liquid level of the cleaning liquid is higher than the height of the cleaning frame 8 (see fig. 3), the cleaning liquid flows into the cleaning frame 8, and the cleaning liquid fully wraps the surface of the glass mold 7, so that oil stains on the surface of the glass mold 7 can be removed preliminarily. And impurities such as chips on the surface of the glass mold 7 can fall into the cleaning tank 1 due to wetting with the cleaning liquid.

As shown in fig. 3, a water tank 11 is further disposed below the cleaning tank 1, and a circulating pump 12 is disposed between a liquid outlet of the water tank 11 and a liquid inlet of the cleaning tank 1. The liquid outlet of the cleaning tank 1 is connected with the liquid inlet of the water tank 11 through a connecting pipe 19. An electrically controlled valve (not shown) is arranged in the connecting pipe 19. The water tank 11 is used to circulate the cleaning liquid in the cleaning tank 1. The cleaning liquid circularly flows between the water tank 11 and the cleaning tank 1 under the driving action of the circulating pump 12, and at this time, because the cleaning liquid in the cleaning tank 1 is in a flowing state, the cleaning liquid can take away oil stains and particle impurities on the surface of the glass mold 7 and recover the oil stains and the particle impurities into the water tank 11. The cleaning liquid flows in the direction B shown in the drawing in the cleaning tank 1, and since the drain holes 81 on both sides of the cleaning frame 8 face or are opposite to the water flow direction B, the cleaning liquid flows into the cleaning frame 8 from the drain hole 81 on the right side in fig. 3 and flows out of the cleaning frame 8 from the drain hole 81 on the left side, and when flowing out of the cleaning frame 8, the cleaning liquid carries away the cleaned oil stains and particulate impurities, and the oil stains and particulate impurities flow into the water tank 11. The provision of the weep hole 81 thus improves the cleaning efficiency. Two filter screens 13 are also arranged in the water tank 11. The filter screen 13 separation is between the income liquid mouth (left end) and the liquid outlet (right-hand member) of water tank 11, must pass through filter screen 13 when the washing liquid flows to the liquid outlet from the income liquid mouth of water tank 11 for filter the impurity in the liquid that comes. The two filter screens 13 are arranged to improve the filtering effect. The number of passes of the filter 13 is not particularly limited. In order to achieve a good balance between the fluidity of the liquid and the filtering effect, the filter screen 13 of the present embodiment is provided with two channels.

After being soaked in the cleaning tank 1 and subjected to preliminary cleaning, the glass mold 7 is grasped on the conveyor 2 by the robot arm 6 and rotated by 90 ° so that the leak holes 81 face to the outside of both sides. The conveyor 2 is rotated by a motor not shown in the figure to transport the glass mold 7 downstream.

As shown in fig. 4, the outer periphery of the conveyor belt 2 is also provided with a closed sheet metal cover 3. Still be provided with a plurality of air nozzles 4 in the sheet metal cover 3, air nozzle 4 distributes in the direction of transfer's of conveyer belt 2 both sides. The air nozzles 4 may also be distributed on only one side of the conveyor belt 2. The jet direction of the air nozzle 4 is directed to the upper surface of the conveyor belt 2, and the glass mold 7 in the cleaning frame 8 is swept to remove liquid and particle impurities on the surface of the glass mold 7. High-pressure gas is introduced into the gas nozzle 4, so that the purging effect is better, and the purging effect can be adjusted by adjusting the pressure of the high-pressure gas. And because the glass mold 7 is continuously blown and swept in the conveying process on the conveyor belt 2, the surfaces of the glass mold 7 are sequentially blown and swept by the plurality of air nozzles 4 distributed, and the final cleaning effect is better.

And a heating device can be arranged on the air supply pipeline of the air nozzle 4, so that the compressed air is heated into hot air which sweeps the surface of the glass mold 7, and the drying efficiency is higher.

The end (corresponding to 2 right-hand members of conveyer belt, the discharge end promptly) of panel beating cover 3 still is provided with vapor fog recovery mechanism 5, and vapor fog recovery mechanism 5 includes the air exhauster not shown in the figure for extract vapor fog and flying dust in the panel beating cover 3, thereby can prevent that vapor fog and flying dust from giving off in the surrounding environment, make the operational environment more excellent. The sheet metal cover 3 is further provided with a vent hole (not shown) for pressure balance.

The discharge end (the right-hand member in fig. 4) of conveyer belt 2 is provided with infrared inductive sensor 14, and infrared inductive sensor 14 is used for monitoring the material on the conveyer belt 2 to can be when glass mold 7 transmits conveyer belt 2 discharge end, stop conveyer belt 2 and take out glass mold 7 through the door of opening that does not show on the sheet metal cover 3 with washing frame 8.

The glass mold cleaning device of the embodiment adopts a glass mold cleaning method which comprises the following steps:

s1, soaking a glass mold by using a cleaning tank loaded with cleaning liquid, circulating the cleaning liquid between the cleaning tank and a water tank by using a circulating pump, and filtering impurities in the cleaning liquid by using at least one layer of filter screen arranged in the water tank;

s2, conveying the glass mold on a conveying belt with a closed sheet metal cover surrounding the conveying belt, and spraying compressed gas to the glass mold for blowing and sweeping through air nozzles distributed in the sheet metal cover along the extension direction of the conveying belt in the conveying process;

and S3, absorbing fly ash in the sheet metal cover through a vapor recovery mechanism at the tail end of the sheet metal cover.

Further, a washing frame 8 is used to load and transport the glass mold 7.

Furthermore, two opposite side walls of the cleaning frame 8 are provided with leakage holes 81 for the cleaning liquid and the compressed gas to pass through.

In summary, in the glass mold cleaning apparatus and the glass mold cleaning method adopted in the present embodiment, the glass mold 7 is first soaked in the cleaning solution, so that oil stains can be removed, and due to the soaking effect, particle impurities (chips and the like) on the surface of the glass mold 7 are more easily dropped into the cleaning tank 1 from the surface of the glass mold 7, and the cleaning solution flowing in the cleaning tank 1 can take away the oil stains and the particle impurities, so that the glass mold 7 achieves a preliminary cleaning effect. Then the glass mold 7 is grabbed onto the conveyor belt 2 by the mechanical arm 6, conveyed on the conveyor belt 2 and continuously blown by the air nozzle 4 in the conveying process, the surface of the glass mold 7 is dried, impurities on the surface of the glass mold 7 are blown off, and the effect of further cleaning is achieved. An exhaust fan in the steam fog recovery mechanism 5 at the tail end of the sheet metal cover 3 extracts gas and particles in the sheet metal cover 3 to prevent the gas and the particles from being emitted to the surrounding environment, so that the surrounding working environment is better.

The above embodiments are merely illustrative of the technical concept and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the content of the present invention and implement the invention, and not to limit the scope of the invention, and all equivalent changes or modifications made according to the spirit of the present invention should be covered by the scope of the present invention.

Claims

1. A glass mold cleaning device, comprising:

a cleaning tank (1);

the washing device comprises a conveyor belt (2), wherein the conveyor belt (2) is arranged at the downstream of the washing tank (1), a closed metal plate cover (3) is wrapped at the periphery of the conveyor belt (2), air nozzles (4) distributed along the extension direction of the conveyor belt (2) are arranged in the metal plate cover (3), and a steam fog recovery mechanism (5) is arranged at the tail end of the metal plate cover (3);

a robot (6), the robot (6) being configured to convey a glass mold (7) between the cleaning bath (1) and a starting end of the conveyor (2);

the cleaning device is characterized by further comprising a water tank (11) and a circulating pump (12), wherein the circulating pump (12) is connected between the water tank (11) and the cleaning tank (1), and at least one layer of filter screen (13) which is blocked between a liquid inlet and a liquid outlet of the water tank (11) is arranged in the water tank (11);

the glass mold cleaning device is characterized by further comprising a cleaning frame (8) used for loading the glass mold (7), the manipulator (6) is configured to be capable of grabbing the cleaning frame (8), leak holes (81) are formed in two opposite side walls of the cleaning frame (8), and end faces corresponding to the leak holes (81) are smooth planes.

2. The glass mold cleaning device according to claim 1, characterized in that: the manipulator (6) comprises a pneumatic clamping jaw (61) and a rotating mechanism (62) for rotating the pneumatic clamping jaw (61).

3. The glass mold cleaning device according to claim 1, characterized in that: the glass mold cleaning device is characterized by further comprising an incoming material placing table (9), wherein a positioning block (10) used for positioning the cleaning frame (8) is arranged on the incoming material placing table (9), and the manipulator (6) is configured to convey the glass mold (7) between the incoming material placing table (9) and the cleaning tank (1).

4. The glass mold cleaning device according to claim 1, wherein: two opposite side walls of the cleaning frame (8) are provided with leakage holes (81).

5. The glass mold cleaning device according to claim 4, characterized in that: and the top edge of the side wall adjacent to the leak hole (81) is provided with an outward-extending support strip (82), and the support strip (82) is used for lifting the manipulator (6).

6. The glass mold cleaning device according to claim 1, wherein: the discharging end of the conveying belt (2) is further provided with an infrared induction sensor (14), and the infrared induction sensor (14) is used for monitoring materials on the conveying belt (2).

7. A method for cleaning a glass mold, comprising:

8. The glass mold cleaning method according to claim 7, characterized in that: a washing frame is used to load and transport the glass molds.

9. The glass mold cleaning method according to claim 8, characterized in that: two opposite side walls of the cleaning frame are provided with leakage holes for the cleaning liquid and the compressed gas to pass through.