CN115446011B - Glass mold cleaning device - Google Patents

Abstract

The invention relates to a glass mould cleaning device, which comprises: a cleaning tank, a water tank and a circulating pump; the conveyor belt is arranged at the downstream of the cleaning tank, a closed sheet metal cover is wrapped on the periphery of the conveyor belt, air nozzles distributed along the extending direction of the conveyor belt are arranged in the sheet metal cover, and an air fog recovery mechanism is arranged at the tail end of the sheet metal cover; and a robot configured to carry the glass mold between the cleaning tank and the start end of the conveyor. Also provided is a glass mold cleaning method comprising: s1, soaking a glass die in a cleaning tank, circulating cleaning liquid between the cleaning tank and a water tank through a circulating pump, and filtering impurities in the cleaning liquid through a filter screen; s2, conveying the glass mold on a conveyor belt, and spraying compressed gas to blow the glass mold in the conveying process; s3, sucking flying dust through the steam fog recycling mechanism. The cleaning liquid is used for soaking the glass mould to primarily remove oil stains and impurities on the surface of the glass mould, and then high-pressure gas is blown in a closed environment to further clean the glass mould.

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 manufacturing requires the use of glass molds. When a glass mold is produced, attachments such as a chip liquid and stains are present on the surface of the glass mold, and cleaning is required. The method for removing the attachments on the surface of the glass mold is a spraying method as disclosed in "CN211160943U" (a glass mold oil washing device), "CN211217744U" (a glass mold oil washing device), "CN201783479U" (a mold cleaning device), and the method is to spray the cleaning liquid onto the surface of the glass mold and recover the cleaning 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 above purpose, the invention adopts the following technical scheme:

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 sheet metal cover is wrapped on the periphery of the conveying belt, air nozzles distributed along the extending direction of the conveying belt are arranged in the sheet metal cover, and an air fog recovery mechanism is arranged at the tail end of the sheet metal cover;

a robot configured to carry glass molds between the wash tank and a start end of the conveyor;

the cleaning tank also comprises a water tank and a circulating pump, wherein the circulating pump is connected between the water tank and the cleaning tank. At least one filter screen which is blocked between a liquid inlet and a liquid outlet of the water tank is arranged in the water tank;

the cleaning device is characterized by further comprising a cleaning frame for loading the glass mold, wherein the manipulator is configured to grasp the cleaning frame, the two opposite side walls of the cleaning frame are provided with leakage holes, and the end surfaces corresponding to the leakage holes are smooth planes.

Preferably, the manipulator comprises a pneumatic jaw and a rotation mechanism for rotating the pneumatic jaw.

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

Further, a top edge of the side wall adjacent to the leak hole is provided with a flared supporting strip, and the supporting strip is used for lifting the manipulator.

Preferably, the discharge end of the conveyor belt is further provided with an infrared sensor, and the infrared sensor is used for monitoring materials on the conveyor belt.

Also provided is a method of cleaning a glass mold, comprising:

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

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

s3, sucking flying dust in the sheet metal cover through a steam fog recycling mechanism at the tail end of the sheet metal cover.

Preferably, a cleaning frame is employed to load and transport the glass mold.

Further, 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 immersed into the cleaning tank loaded with the cleaning liquid, so that the cleaning liquid is fully contacted with the surface of the glass mold, impurities such as chips attached to the surface of the glass mold are separated from the glass mold, the impurities are immersed into the cleaning liquid, the glass mold is placed on the conveyor belt, and the surface of the glass mold is purged by using the air nozzle in the conveying process of the conveyor belt. According to the cleaning method, the glass die is fully contacted with the cleaning liquid in an immersion mode to clean oil stains on the surface, so that a primary cleaning effect is achieved, and the air nozzle can generate a large spraying force to further clean and dry the glass die. Is a breakthrough improvement over spray patterns and produces the benefit of improved cleaning quality.

Drawings

Some specific embodiments of the invention will be described in detail hereinafter by way of example and not by way of limitation with reference to the accompanying drawings. The same reference numbers will be used throughout the drawings to refer to the same or like parts or portions. It will be appreciated by those skilled in the art that the drawings are not necessarily drawn to scale. In the accompanying drawings:

FIG. 1 is a schematic illustration of the cooperation of a cleaning tank, conveyor belt and robot in a preferred embodiment of the invention;

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

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

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

wherein 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. pneumatic clamping jaws; 62. a rotation mechanism;

7. a glass mold;

8. cleaning a frame; 81. a leak hole; 82. a support bar;

9. a material receiving and placing table;

10. a positioning block;

11. a water tank;

12. a circulation pump;

13. a filter screen;

14. an infrared sensor;

15. a sliding table;

16. a guide rail;

17. a slide plate;

18. a lifting plate;

19. and (5) connecting pipes.

Detailed Description

The following description of the embodiments of the present invention will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the invention are shown. 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.

In the description of the present invention, it should be noted that the directions or positional relationships indicated by the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured 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 of the different embodiments of the present invention described below may be combined with each other as long as they do not collide with each other.

The glass mold cleaning device shown in fig. 1 mainly comprises a cleaning tank 1, a conveyor belt 2 and a manipulator 6. The manipulator 6 grabs the glass die 7 into the cleaning tank 1, the glass die 7 is immersed in the cleaning liquid contained in the cleaning tank 1, and various cleaning liquids in the prior art can be used as the cleaning liquid. The robot 6 then grips the glass mould 7 onto the conveyor belt 2 and transports it in a remote direction. As shown in fig. 4, during the conveyance of the glass mold 7 on the conveyor 2, the glass mold 7 is further cleaned on the surface by blowing the glass mold 7 by the air nozzle 4, and dried. Detailed description is as follows.

As shown in fig. 1 and 2, an incoming material placing table 9 is arranged on the outer side of the cleaning tank 1, and a manipulator 6 is used for grabbing a glass mold 7 on the incoming material placing table 9. The glass mold 7 is loaded in the cleaning frame 8 and placed on the supply table 9 by an operator. And the incoming material placing table 9 is provided with a positioning block 10, and the positioning block 10 is provided with a right-angle groove for positioning the cleaning frame 8. The number of the positioning blocks 10 can be two, and the positioning blocks are distributed on two sides of the incoming material placing table 9. After the cleaning frame 8 is positioned, the cleaning frame is convenient for the manipulator 6 to grasp more accurately. And the glass mould 7 is placed in the cleaning frame 8, so that the glass mould 7 can be conveniently conveyed.

As shown in fig. 2, the left and right sides of the top edge of the cleaning frame 8 are provided with a flared supporting strip 82, and the supporting strip 82 extends through the entire length of the top edge of one side. The top edges of the other two sides are not provided with the supporting strips 82, and the side walls of the corresponding end parts of the cleaning frame 8 on the side without the supporting strips 82 are provided with four leakage holes 81, so that the occupied area of the leakage holes 81 is large enough to occupy almost the whole end face. The number and shape of the weep holes 81 are not particularly limited. The holes 81 facilitate the flow of cleaning liquid into the cleaning frame 8, and the holes 81 facilitate the purging of the glass mold 7 by the air nozzles 4 (see fig. 4). The top edge of the end surface corresponding to the leak hole 81 is not provided with the supporting strip 82, that is, the end surface corresponding to the leak hole 81 is a smooth plane, and the no supporting strip 82 does not block the air injection of the air nozzle 4 (the air nozzle 4 may be blown into the leak hole 81 from the upper side obliquely downwards), thereby improving the blowing effect of the air nozzle 4.

As shown in fig. 1, the manipulator 6 is connected to a lifting plate 18, the lifting plate 18 is connected to a slide plate 17 in a lifting manner, the slide plate 17 is mounted on a guide rail 16 and can slide along the guide rail 16, and the guide rail 16 extends transversely to the slide table 15. The two parallel guide rails 16 are arranged, the guide rails 16 are distributed on the side surface of the sliding table 15 in the up-down direction, and compared with one guide rail 16, the two guide rails 16 enable the manipulator 6 to be more stable. The length of the slide table 15 and the guide rail 16 covers part of the incoming material placing table 9, the cleaning tank 1 and the start end of the conveyor belt 2, so that the robot arm 6 can grasp and transfer the cleaning frame 8 between the incoming material placing table 9, the cleaning tank 1 and the conveyor belt 2.

The robot arm 6 includes a pneumatic clamping jaw 61 and a rotation mechanism 62. The pneumatic clamping jaw 61 is capable of clamping and holding the supporting strip 82, thereby lifting the cleaning frame 8. The rotary mechanism 62 rotates the pneumatic gripper 61 using a rotary cylinder. In this example, when the cleaning frame 8 is gripped onto the conveyor belt 2 from the cleaning tank 1, the cleaning frame 8 is rotated by 90 ° so that the holes 81 in the cleaning frame 8 are located on both sides (both sides with respect to the conveying direction of the conveyor belt 2), thereby facilitating the blowing of the high-pressure gas of the air nozzle 4 (see fig. 4) toward the glass mold 7 through the holes 81.

The cleaning frame 8 is loaded with cleaning liquid. After the cleaning frame 8 is placed into the cleaning tank 1 by the robot 6, the liquid level of the cleaning liquid is higher than 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 the oil stain on the surface of the glass mold 7 can be primarily removed. And impurities such as chips on the surface of the glass mold 7 can fall into the cleaning tank 1 due to infiltration of the cleaning liquid.

As shown in fig. 3, a water tank 11 is further disposed below the cleaning tank 1, and a circulation 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 for circulating the cleaning liquid in the cleaning tank 1. The cleaning liquid circulates between the water tank 11 and the cleaning tank 1 under the driving action of the circulating pump 12, and at this time, oil stains and particle impurities on the surface of the glass mold 7 can be taken away and recovered into the water tank 11 because the cleaning liquid in the cleaning tank 1 is in a flowing state. The cleaning liquid flows in the direction B shown in the drawing in the cleaning tank 1, and since the holes 81 on both sides of the cleaning frame 8 face or face the water flow direction B, the cleaning liquid flows into the cleaning frame 8 from the holes 81 on the right side in fig. 3, flows out of the cleaning frame 8 from the holes 81 on the left side, brings out the oil dirt and the particulate impurities which are washed out when flowing out of the cleaning frame 8, and flows into the water tank 11. The provision of the weep holes 81 thus improves the cleaning efficiency. Two filter screens 13 are also arranged in the water tank 11. The filter screen 13 is blocked between the liquid inlet (left end) and the liquid outlet (right end) of the water tank 11, and when the cleaning liquid flows from the liquid inlet to the liquid outlet of the water tank 11, the cleaning liquid is used for filtering impurities in the liquid. The two filter screens 13 are arranged, so that the filtering effect is improved. The number of the filter screen 13 is not particularly limited. In order to achieve a better balance between the fluidity of the liquid and the filtering effect, the filter screen 13 of this example is provided in two ways.

After the glass mold 7 is soaked in the cleaning tank 1 and is primarily cleaned, the glass mold is grasped on the conveyor belt 2 by the manipulator 6 and rotated by 90 degrees, so that the leakage holes 81 face to the outside of the two sides. The conveyor 2 is driven by a motor, not shown, to circulate and transport the glass moulds 7 downstream.

As shown in fig. 4, the periphery of the conveyor belt 2 is also provided with a closed sheet metal cover 3. A plurality of air nozzles 4 are also arranged in the sheet metal cover 3, and the air nozzles 4 are distributed on two sides of the conveying direction of the conveying belt 2. 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 points to the upper surface of the conveyor belt 2, and the glass mould 7 in the cleaning frame 8 is purged to remove liquid and particle impurities on the surface of the glass mould 7. The high-pressure gas is introduced into the air 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 die 7 is continuously purged in the process of being transmitted on the conveyor belt 2, the surface of the glass die 7 is sequentially purged by the distributed air nozzles 4, and the final cleaning effect is better.

Heating devices can be arranged on the air supply pipeline of the air nozzle 4, so that compressed air is heated to be hot air, and the hot air is blown to the surface of the glass die 7, so that the drying efficiency is higher.

The tail end (corresponding to the right end of the conveyor belt 2, namely the discharge end) of the sheet metal cover 3 is further provided with a vapor recovery mechanism 5, and the vapor recovery mechanism 5 comprises an exhaust fan which is not shown in the drawing and is used for extracting vapor and flying dust in the sheet metal cover 3, so that the vapor and the flying dust can be prevented from being emitted to the surrounding environment, and the operation environment is better. The sheet metal cover 3 is also provided with a vent hole (not shown) for balancing pressure.

The discharge end (right end in fig. 4) of the conveyor belt 2 is provided with an infrared sensor 14, the infrared sensor 14 being used for monitoring the material on the conveyor belt 2, so that the conveyor belt 2 can be stopped and the glass mould 7 together with the cleaning frame 8 can be taken out through an opening door, not shown, on the sheet metal hood 3 when the glass mould 7 is transferred to the discharge end of the conveyor belt 2.

The glass mold cleaning device of the example adopts the following glass mold cleaning method:

s1, soaking a glass die in a cleaning tank loaded with cleaning liquid, 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 conveyor belt with a sealed sheet metal cover surrounding the periphery, and spraying compressed gas to the glass mold through air nozzles distributed in the sheet metal cover along the extending direction of the conveyor belt for blowing in the conveying process;

s3, sucking flying dust in the sheet metal cover through a steam fog recycling mechanism at the tail end of the sheet metal cover.

Further, a cleaning frame 8 is employed to load and transport the glass mold 7.

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

In summary, in the glass mold cleaning device and the glass mold cleaning method used in the present embodiment, the glass mold 7 is soaked in the cleaning solution, so that the oil stain can be removed, and due to the soaking effect, the particle impurities (such as chips) on the surface of the glass mold 7 also fall into the cleaning tank 1 more easily from the surface of the glass mold 7, and the cleaning solution flowing in the cleaning tank 1 can take away the oil stain and the particle impurities, so that the glass mold 7 achieves the primary cleaning effect. Then the glass mould 7 is grabbed onto the conveyor belt 2 by the manipulator 6, is transported on the conveyor belt 2, and is continuously purged by the air nozzle 4 in the transportation process, the surface of the glass mould 7 is dried, and impurities on the surface of the glass mould 7 are purged, so that the effect of further cleaning is achieved. The exhaust fan in the vapor recovery mechanism 5 at the tail end of the sheet metal cover 3 extracts gas and particulate matters in the sheet metal cover 3, prevents the gas and particulate matters from being emitted to the surrounding environment, and ensures that the surrounding operation environment is better.

The above embodiments are only for illustrating the technical concept and features of the present invention, and are intended to enable those skilled in the art to understand the present invention and to implement the same, but are not intended to limit the scope of the present invention, and all equivalent changes or modifications made according to the spirit of the present invention should be included in the scope of the present invention.

Claims (5)

1. A glass mold cleaning apparatus, comprising:

a cleaning tank (1);

the conveying belt (2), the conveying belt (2) is arranged at the downstream of the cleaning tank (1), a closed sheet metal cover (3) is wrapped around the periphery of the conveying belt (2), air nozzles (4) distributed along the extending direction of the conveying belt (2) are arranged in the sheet metal cover (3), and an aerosol recovery mechanism (5) is arranged at the tail end of the sheet metal cover (3);

a robot (6), the robot (6) being configured to carry glass moulds (7) between the washing tank (1) and a start end of the conveyor belt (2);

the water tank (11) is internally provided with at least one layer of filter screen (13) which is blocked between a liquid inlet and a liquid outlet of the water tank (11);

the cleaning device comprises a glass die (7), and is characterized by further comprising a cleaning frame (8) for loading the glass die (7), wherein the mechanical arm (6) is configured to grasp the cleaning frame (8), two opposite side walls of the cleaning frame (8) are provided with leakage holes (81), the corresponding end surfaces of the leakage holes (81) are smooth planes, when in cleaning, the leakage holes (81) on two sides of the cleaning frame (8) face or face away from the water flow direction, cleaning liquid flows into the cleaning frame (8) from the leakage holes (81) on one side, flows out of the cleaning frame (8) from the leakage holes (81) on the other side, and high-pressure gas is blown to the glass die (7) through the leakage holes (81) when in drying;

the manipulator (6) comprises a pneumatic clamping jaw (61) and a rotating mechanism (62) for rotating the pneumatic clamping jaw (61);

the glass mold cleaning device further comprises an incoming material placing table (9), wherein a positioning block (10) for positioning the cleaning frame (8) is arranged on the incoming material placing table (9), and the mechanical arm (6) is configured to convey the glass mold (7) between the incoming material placing table (9) and the cleaning tank (1);

the top edge of the side wall adjacent to the leak hole (81) is provided with a abduction supporting strip (82), and the supporting strip (82) is used for lifting the manipulator (6).

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

3. A glass mold cleaning method using the glass mold cleaning apparatus according to claim 1 or 2, characterized by comprising:

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

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

s3, sucking flying dust in the sheet metal cover through a steam fog recycling mechanism at the tail end of the sheet metal cover.

4. A glass mold cleaning method according to claim 3, wherein: a cleaning frame is used to load and transport the glass mold.

5. The glass mold cleaning method according to claim 4, wherein: leakage holes are formed in two opposite side walls of the cleaning frame for the cleaning liquid and the compressed gas to pass through.