CN211989483U - Air inlet and exhaust system for adhesive sealing equipment - Google Patents

Abstract

The utility model discloses an advance exhaust system for sealing glue equipment advances exhaust system, advance exhaust system and include first inlet air channel and second inlet air channel, first inlet air channel from gluing the room intercommunication to the position of the neighbouring cold wind room of the side that moves on the object to set first HEPA filter at first inlet air channel, second inlet air channel moves the lower part intercommunication of side from the object to the position of the neighbouring cold wind room of the side that moves under the object, and set second HEPA filter at second inlet air channel. Therefore, the processed object can be prevented from being polluted by impurities and glue dripping in the production process, and the yield of finished products is improved.

Description

Air inlet and exhaust system for adhesive sealing equipment

Technical Field

The present invention relates to an air intake and exhaust system, and more particularly to an air intake and exhaust system for a molding apparatus.

Background

At present, in the process of covering and manufacturing a metal substrate, a metal foil is subjected to sealing and manufacturing by a sealing device, the sealing device comprises a glue room, an object upper moving side, a cold air room and an object lower moving side, the object upper moving side and the object lower moving side are arranged above the glue room at intervals, the cold air room is arranged above the object upper moving side and the object lower moving side, the metal foil is introduced into the glue room filled with resin glue through a transmission device, the surface of the metal foil is uniformly covered with the glue, and then the metal foil is correspondingly arranged through an oven and an air inlet and exhaust system, so that the sealing and manufacturing of the metal foil are achieved.

The existing air intake and exhaust system has only simple filtering and heating effects, so that fine particles and impurities contained in air are not intercepted and removed, and polymers in an air pipe are directly blown to a processed object. The air intake device is arranged at the lower part of the moving side under the object, part of impurities fall into the oven due to gravity during the periodic cleaning, and the fallen impurities are blown to the processed object again by hot air, so that the impurities are generated. Moreover, each exhaust outlet is arranged below the cold air blocking surface, and due to the inherent characteristics of the glue, the exhaust gas has high concentration, and the exhaust gas is blocked by the cold air to form viscous flow-shaped residues, and glue dripping is formed after accumulation.

In view of the above, the inventor of the present invention is interested in studying the above-mentioned shortcomings of the prior art and cooperating with the application of the theory to solve the above-mentioned problems as much as possible, which is the improved objective of the inventor.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an advance exhaust system for sealing glue equipment, wherein by the processing object in process of production, can avoid suffering impurity and the pollution influence of glue dripping, and then promote the yield of finished product.

In order to achieve the above object, the present invention provides an air intake and exhaust system for a molding equipment, the glue sealing equipment comprises a glue room, an object upper moving side, a cold air room and an object lower moving side, the object upper moving side and the object lower moving side are arranged above the glue room at intervals, the cold air room is positioned above the object upper moving side and the object lower moving side, wherein the air intake and exhaust system comprises a first air intake channel and a second air intake channel, the first air intake channel is communicated from the rubber room to the position of the moving side of the object, which is adjacent to the cold air room, and the first air intake channel is provided with a first HEPA filter, the second air inlet channel is communicated from the lower part of the upper moving side of the object to the position of the lower moving side of the object, which is adjacent to the cold air room, and a second HEPA filter is arranged on the second air inlet channel.

In some embodiments, the first air intake channel communicates the glue house with the moving side of the object through a first air duct.

In some embodiments, the first air duct is provided with a filter, a blower and a heater in sequence from the glue house to the upper moving side of the object, and the first HEPA filter is provided between the heater and the upper moving side of the object.

In some embodiments, the first HEPA filter is disposed adjacent to the cold air room and a location on a moving side of the object.

In some embodiments, the second air intake channel is connected to the upper moving side of the subject and the lower moving side of the subject through a second air duct.

In some embodiments, the second air duct is provided with a filter, a blower and a heater in this order from the upper moving side of the object to the lower moving side of the object, and the second HEPA filter is provided between the heater and the lower moving side of the object.

In some embodiments, the second HEPA filter is disposed adjacent to the cold air room and the lower moving side of the object.

In some embodiments, the heat storage type incinerator further comprises a first exhaust passage which is communicated from the lower portion of the lower moving side of the object to a heat storage type incinerator through an air duct.

In some embodiments, the heat accumulating type incinerator further comprises a second air exhaust channel, and the second air exhaust channel is communicated from the glue room to the heat accumulating type incinerator through an air pipe.

In some embodiments, a fan is disposed in each of the first exhaust channel and the second exhaust channel.

The utility model discloses still have following efficiency, set up inlet air channel through the top that removes the side under the object, can avoid regular cleanness, let partial impurity fall into the oven because of gravity to blow once more by the air inlet and generate impurity on being processed the thing. By arranging the air exhaust channel below the moving side under the object, the generation of glue dripping can be avoided. Moreover, the machine can improve the shutdown cleaning time and save the labor cost, and can also improve the productivity and reduce the production cost.

Drawings

Fig. 1 is a schematic view of the air intake and exhaust system applied to the sealing equipment.

Symbolic illustration in the drawings:

1, an air inlet and exhaust system;

10 a first air inlet channel;

11 a first air duct;

12 a filter;

13, a fan;

14 a heater;

15 a first HEPA filter;

20 a second air inlet channel;

21 a second air duct;

22 a filter;

23, a fan;

24 a heater;

25 a second HEPA filter;

30 a first exhaust duct;

31 a fan;

40 a second exhaust channel;

41 a fan;

50 regenerative incinerator;

8, sealing equipment is used;

81 glue rooms;

811 resin glue;

812 a feed roller;

813 discharge rollers;

82 on-object moving side;

821 a baking device;

822 baking the channel;

83 cold air rooms;

831 rollers;

84 object lower moving side;

841 a baking device;

842 a baking channel;

9 processing the object.

Detailed Description

The following detailed description and technical contents of the present invention are described with reference to the accompanying drawings, however, the accompanying drawings are only provided for reference and illustration, and are not intended to limit the present invention.

Referring to fig. 1, the present invention provides an air intake and exhaust system for a sealing device, the sealing device 8 mainly includes a glue room 81, an object upper moving side 82, a cool air room 83 and an object lower moving side 84, wherein the object upper moving side 82 and the object lower moving side 84 are parallel to each other and are vertically disposed above the glue room 81 at an interval, and the cool air room 83 is disposed above the object upper moving side 82 and the object lower moving side 84.

The inner space of the glue house 81 is provided with a resin glue 811, and a pair of feeding rollers 812 and a discharging roller 813 are disposed.

The object moving side 82 mainly includes a pair of baking devices 821 spaced apart from each other, and a baking path 822 is formed between the baking devices 821, and the baking path 822 can provide a movement of an object 9 to be processed (e.g., copper foil).

Three rollers 831 are spaced apart from each other in the cooling air chamber 83, and each roller 831 is substantially arranged in a triangle to allow the objects 9 to be processed to sequentially surround.

The object lower moving side 84 mainly includes a pair of baking devices 841 arranged at intervals, and a baking path 842 is formed between the baking devices 841, and the baking path 842 can provide the movement of the object 9 to be processed.

The air intake and exhaust system 1 mainly includes a first air intake channel 10 and a second air intake channel 20.

The first air intake passage 10 mainly includes a first air duct 11, the first air duct 11 is connected from the glue room 81 to the position of the object upper moving side 82 adjacent to the cold air room 83, and a filter 12, a blower 13, a heater 14 and a first HEPA filter 15 are sequentially disposed along each position of the first air duct 11, and the air inside the first air duct 11 enters the upper portion of the baking passage 822 after passing through the first HEPA filter 15, wherein the first HEPA filter 15 is disposed between the heater 14 and the object upper moving side 82, and is disposed adjacent to the position of the cold air room 83 and the object upper moving side 82.

Among them, the HEPA (High-Efficiency Particulate Air) filter screen is a device for Air purification, has a filtering effect of DOP above 99.97% for particles with a particle size of 0.3 μm, is usually made of chemical fibers (for example, polypropylene fibers, i.e., polypropylene fibers, or polyester fibers, i.e., polyester-based non-woven fabrics) or glass fibers arranged randomly, has a diameter of about 0.5 to 2.0 μm, and is mainly used for removing particles with a size above 0.5 μm through a microscopic flocculent structure.

The second air duct 20 mainly includes a second air duct 21, the second air duct 21 is connected from the lower portion of the upper moving side 82 of the object to the position of the lower moving side 84 of the object adjacent to the cool air chamber 83, and a filter 22, a blower 23, a heater 24 and a second HEPA filter 25 are sequentially disposed along each portion of the second air duct 21, and the air inside the second air duct 21 passes through the second HEPA filter 25 and then enters the upper portion of the baking path 842, wherein the second HEPA filter 25 is disposed between the heater 24 and the lower moving side 84 of the object and is disposed adjacent to the position of the cool air chamber 83 and the lower moving side 84 of the object.

Further, the air intake and exhaust system 1 of the present invention further includes a first air exhaust channel 30, which is connected to a Regenerative Thermal Oxidizer (RTO) 50 from the lower portion of the object lower moving side 84 (or the adjacent glue house 81) through an air duct, and it utilizes the principle of high temperature oxidation to decompose the volatile organic gas VOC generated by various industrial processes into steam and carbon dioxide through the combustion process at sufficient temperature and reaction time, and to recover the high heat generated by oxidation by a heat storage device to reduce the amount of heat energy fuel required by the system; wherein a fan 31 is provided inside the first exhaust duct 30.

Further, the air intake and exhaust system 1 of the present invention further includes a second air exhaust channel 40, which is communicated to the heat accumulating type incinerator 50 from the glue room 81 through an air pipe, wherein a fan 41 is disposed inside the second air exhaust channel 40.

During the production, the object 9 to be processed is covered with resin glue 811, and then is transferred upward from the baking path 822 of the object upper moving side 82 by the rolling of each feed roller 812, and is baked by the baking device 821 during the transfer, and the gas sent out from the glue house 81 passes through the first air duct 11, the filter 12, the fan 13, the heater 14 and the first HEPA filter 15, and then enters the upper part of the baking path 822 after passing through the first HEPA filter 15; then the processed object 9 enters the cold air chamber 83, is continuously transferred by the rollers 831, enters the baking channel 842 of the object lower moving side 84, and is in the process of moving down the processed object 9; meanwhile, the gas sent from the moving side 82 of the object passes through the second air duct 21, the filter 22, the blower 23, the heater 24 and the second HEPA filter 25, and then enters the upper part of the baking channel 842 after passing through the second HEPA filter 25, so that the processed object 9 can be prevented from being contaminated by impurities and adhesive drops during the production process, and the yield of the finished product can be improved.

To sum up, the utility model is used for sealing into air exhaust system of glue equipment, can reach anticipated use purpose certainly, and solve known disappearance.

Claims (10)

1. An air intake and exhaust system for a sealing equipment, the sealing equipment comprises a glue room, an object upper moving side, a cold air room and an object lower moving side, the object upper moving side and the object lower moving side are arranged above the glue room at intervals, the cold air room is positioned above the object upper moving side and the object lower moving side, the air intake and exhaust system is characterized by comprising a first air intake channel and a second air intake channel, the first air intake channel is communicated from the glue room to the position, adjacent to the cold air room, of the object upper moving side, a first HEPA filter is arranged on the first air intake channel, the second air intake channel is communicated from the lower part of the object upper moving side to the position, adjacent to the cold air room, of the object lower moving side, and a second HEPA filter is arranged on the second air intake channel.

2. The air intake and exhaust system for molding equipment of adhesive sealant as claimed in claim 1, wherein said first air intake channel is connected to said glue room and said movable side of said object through a first air duct.

3. The air intake/exhaust system for molding equipment according to claim 2, wherein a filter, a blower and a heater are provided in this order between said glue room and said moving side of said object, and said first HEPA filter is provided between said heater and said moving side of said object.

4. The air intake and exhaust system for molding equipment according to claim 3, wherein said first HEPA filter is disposed adjacent to said cold air room and a moving side of said object.

5. The air intake and exhaust system for molding equipment of adhesive sealant as claimed in claim 1, wherein said second air intake channel is connected to said upper moving side of said object and said lower moving side of said object by a second air duct.

6. The air intake/exhaust system for molding equipment according to claim 5, wherein a filter, a blower and a heater are provided in this order between said object upper moving side and said object lower moving side, and said second HEPA filter is provided between said heater and said object lower moving side.

7. The air intake and exhaust system for molding equipment according to claim 6, wherein said second HEPA filter is disposed adjacent to said cold air room and said moving side under said object.

8. The air intake/exhaust system for molding equipment according to claim 1, further comprising a first air exhaust passage communicating from a lower portion of the lower moving side of said object to a regenerative incinerator through an air duct.

9. The air intake/exhaust system for molding equipment of claim 8, further comprising a second air exhaust channel connected from said glue house to said regenerative incinerator through an air duct.

10. The air intake/exhaust system for molding equipment according to claim 9, wherein a blower is provided for each of the first air exhaust duct and the second air exhaust duct.

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