CN115303801A - Be used for refrigerated transmission device of glass - Google Patents

Abstract

The invention relates to the technical field of glass cooling, and provides a conveying device for glass cooling, which comprises a conveying belt and a water cooling mechanism, wherein the conveying belt is arranged on the conveying belt; the water cooling mechanism comprises a water cooling tank and a circulating cooling assembly; the top surface of the water cooling tank is provided with a water cooling groove in a downward concave manner, and the middle part of the water cooling groove is convexly provided with a water cooling platform; the top surface of the water cooling platform is higher than or equal to the top surface of the water cooling tank; the width of the conveyor belt in the left-right direction is larger than that of the water cooling table in the left-right direction; a water storage cavity is formed in the water cooling tank, a plurality of water outlet holes are formed in the top surface of the water cooling platform and communicated with the outside atmosphere and the water storage cavity, and cooling water in the water storage cavity is flushed out of the water outlet holes so as to cool the conveyor belt; the input end of the circulating cooling assembly is communicated with the water cooling groove, and the output end of the circulating cooling assembly is communicated with the water storage cavity; the glass cooling device has high glass cooling efficiency, does not need to soak, clean and dry the glass, effectively avoids water stains and improves the printing quality.

Description

Be used for glass refrigerated transmission device

Technical Field

The invention relates to the technical field of glass cooling, in particular to a conveying device for glass cooling.

Background

In some existing glass production lines, glass needs to be printed for multiple times, ink needs to be dried, so that the ink is dried quickly to improve production efficiency, but in the baking process, the glass needs to be cooled before next printing, and the glass needs to be printed once and cooled once; a cooling step of the cooling device of the prior art; the method comprises the steps of first printing, ink drying, cleaning and cooling, drying, second printing and the like, wherein the steps of cold water flushing and cooling, drying by a dryer and the like are required in the processes of cleaning, cooling and drying, the working procedures are complicated, and the efficiency of cold water flushing glass for cooling is low due to the fact that the glass is high when the ink is dried.

Disclosure of Invention

In view of the above drawbacks, the present invention provides a conveying device for cooling glass, which solves the problem of low cooling efficiency of glass in the prior art.

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

a conveying device for cooling glass comprises a conveying belt and a water cooling mechanism; the water cooling mechanism comprises a water cooling tank and a circulating cooling assembly;

the top surface of the water cooling tank is provided with a water cooling groove in a downward concave manner, and the middle part of the water cooling groove is provided with a water cooling platform in a protruding manner;

a water storage cavity is formed in the water cooling tank, a plurality of water outlet holes are formed in the top surface of the water cooling platform, the water outlet holes are communicated with the outside air and the water storage cavity, and cooling water in the water storage cavity is flushed out of the water outlet holes so as to cool the conveying belt;

the input end of the circulating cooling component is communicated with the water-cooling groove, and the output end of the circulating cooling component is communicated with the water storage cavity;

the conveying belt is arranged above the water cooling mechanism and is impervious, and the bottom surface of the conveying belt is pressed against the top surface of the water cooling table and is conveyed forwards.

Preferably, the top surface of the water cooling platform is not lower than the top surface of the water cooling tank; the width of the conveyer belt is larger than that of the water cooling table and smaller than that of the top surface of the water cooling tank.

Preferably, gaps are formed between the periphery of the water cooling table and the side wall of the water cooling groove.

Preferably, the top surface of the water cooling tank is further provided with two fence plates, and the two fence plates are respectively arranged on two sides of the top surface of the water cooling tank.

Preferably, the front end and the rear end of the top surface of the water cooling tank are respectively provided with a water scraping strip.

Preferably, the circulating cooling assembly comprises a circulating water tank, a circulating water pump and a heat exchanger; a water return port is formed in the bottom of the water collecting tank;

the water return port is connected with the circulating water tank through a water pipe; the input end of the circulating water pump is connected with the circulating water tank, the output end of the circulating water pump is connected with the water storage cavity of the water cooling tank, and the cooling pipe of the heat exchanger is arranged in the circulating water tank.

Preferably, the conveying belt is connected with a conveying driving assembly, the conveying driving assembly comprises two rotating shafts and a driving piece, and the conveying belt is wound on the outer side surfaces of the two rotating shafts; the driving piece is used for driving the rotating shaft to rotate so as to drive the conveying belt to convey glass; the top surface of the water cooling table is abutted against the bottom surface of the conveying belt.

Preferably, the conveying belt is a Teflon conveying belt, and the thickness of the conveying belt is 0.1 mm-2 mm.

Preferably, the periphery of the side surface of the water cooling tank is provided with a heat preservation layer, and the heat preservation layer is used for keeping the water temperature of the water cooling tank.

Preferably, the top surface of the water cooling platform is provided with a plurality of flow guide strips.

One of the above technical solutions has the following advantages or beneficial effects:

be used for glass refrigerated transmission device to pass through the transportation area with glass in the forward transportation process, when the transportation area transports glass through the top surface of water-cooling tank, the top surface contact of transportation area and water-cooling platform, the cooling water in the retaining cavity of the inside of water-cooling tank gushes out from the top surface of water-cooling platform under circulative cooling subassembly's effect, the top surface that utilizes the cooling water of gushing out and water-cooling platform carries out the heat exchange with the bottom surface of transportation area, absorb glass's heat, improve glass refrigerated efficiency and effect greatly, need not to soak to glass and wash and dry, the appearance of water damage has effectively been avoided.

Drawings

FIG. 1 is a schematic diagram of the overall architecture of one embodiment of the present invention;

FIG. 2 is a schematic side cross-sectional view of one embodiment of the present invention;

FIG. 3 is an enlarged partial schematic view of FIG. 2;

figure 4 is a top view of one embodiment of the present invention.

Wherein: the water cooling device comprises a conveyor belt 101, a rotating shaft 102, a water cooling mechanism 200, a water cooling box 210, a water cooling groove 211, a water cooling platform 212, a water storage cavity 213, a water outlet hole 214, a fence plate 215, a water scraping strip 216, a water return hole 217, an insulating layer 218, a flow guide strip 219, a circulating cooling assembly 220, a circulating water tank 221, a circulating water pump 222 and a heat exchanger 223.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Furthermore, features defined as "first" and "second" may explicitly or implicitly include one or more of the features for distinguishing between descriptive features, non-sequential, non-trivial and non-trivial.

In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in a specific case to those of ordinary skill in the art.

A conveying apparatus for glass cooling according to an embodiment of the present invention is described below with reference to fig. 1 to 4, and includes a conveyor belt 101 and a water cooling mechanism 200; the water cooling mechanism 200 comprises a water cooling tank 210 and a circulating cooling assembly 220;

the top surface of the water cooling tank 210 is provided with a water cooling groove 211 in a downward concave manner, and the middle part of the water cooling groove 211 is provided with a water cooling platform 212 in a convex manner; the top surface of the water cooling table 212 is higher than or equal to the top surface of the water cooling tank 210; the width of the conveyor belt 101 in the left-right direction is larger than that of the water cooling table 212 in the left-right direction;

a water storage cavity 213 is formed in the water cooling tank 210, a plurality of water outlet holes 214 are formed in the top surface of the water cooling table 212, the water outlet holes 214 are communicated with the outside atmosphere and the water storage cavity 213, and cooling water in the water storage cavity 213 gushes out from the water outlet holes 214 to cool the conveyer belt 101;

the input end of the circulating cooling component 220 is communicated with the water-cooling groove 211, and the output end of the circulating cooling component 220 is communicated with the water storage cavity 213; the conveyer belt is arranged above the water cooling mechanism, the conveyer belt 101 is impermeable, and the bottom surface of the conveyer belt 101 is pressed against the top surface of the water cooling table 212 and is conveyed forwards.

Further, the top surface of the water cooling table is not lower than the top surface of the water cooling tank; the width of the conveyer belt is larger than that of the water cooling table and smaller than that of the top surface of the water cooling tank.

The working principle of the application is as follows: the following will explain a glass print requiring temperature reduction as a specific example. Glass needing cooling is conveyed by the conveyor belt 101 and passes through the water cooling tank 210, the conveyor belt 101 can be conveyed forwards by being attached to the water cooling table 212 on the top surface of the water cooling tank 210, meanwhile, the circulating cooling assembly 220 is started, cooling water is input into the water storage cavity 213 in the water cooling tank 210, along with the rise of the water level in the water storage cavity 213 and under the input pressure of the circulating cooling assembly 220, the cooling water can be contacted with the bottom surface of the conveyor belt 101 when the cooling water gushes out of the water outlet holes 214 on the top surface of the water cooling table 212, so that the bottom surface of the conveyor belt 101 is cooled by the cooling water, the heat of the glass conveyed on the conveyor belt 101 is absorbed, the purpose of cooling the glass is achieved, in addition, the cooling water can also cool the top surface of the water cooling table 212, and when the conveyor belt 101 is contacted with the top surface of the water cooling table 212, the top surface of the water cooling table 212 can also absorb the heat on the conveyor belt 101.

The input end of the circulating cooling assembly 220 is communicated with the water-cooling groove 211, water in the water-cooling groove is absorbed by the circulating cooling assembly 220, the water in the water-cooling groove 211 is cooled and then is input into the water storage cavity 213 again, so that water circulation is realized, the conveying belt 101 and the glass are cooled by the circulating flowing cooling water, and the cooling efficiency of the glass is improved; in addition, the input and output quantities of the circulating cooling assembly 220 are kept consistent, so that the consistency of the water inlet quantity and the water discharge quantity in the water-cooling groove 211 is ensured, and the problem that the glass is wetted by the overhigh water level in the water-cooling groove 211 is avoided.

It should be noted that the top of the water cooling table 212 is not lower than the top of the water cooling tank 210, so as to ensure that the bottom of the conveyor belt 101 contacts the top of the water cooling table 212; the width of the left and right directions of the conveyor belt 101 is larger than the width of the left and right directions of the water cooling table 212, but is smaller than the width of the left and right directions of the top surface of the water cooling tank 210, water on the bottom surface of the conveyor belt 101 can drip back into the water cooling groove 211 from the left and right sides, the water is prevented from dripping outside the water cooling tank 210, and meanwhile, the water is prevented from flowing to the upper surface of the conveying belt.

The edge at water-cooling recess 211 is connected to circulative cooling subassembly 220's input, apopore 214 sets up the top surface middle part position at water-cooling platform 212, in the water circulation, the cooling water gushes out the back from water-cooling platform 212's apopore 214, toward water-cooling platform 212 flow all around and enter into water-cooling recess 211, and under the effect of the surface tension of hydrone, the surface of water on the water-cooling platform 212 can be with the bottom surface mutual adsorption of transportation area 101, thereby the cooling water can fully take 101 contact with the transportation, thereby effectively guarantee the cooling effect.

In addition, the water cooling table 212 can support the conveyer belt 101, so that cooling water is prevented from filling glass on the surface of the conveyer belt 101 due to the fact that the conveyer belt 101 collapses; the corners of the water cooling table 212 can be provided with fillets or chamfers, so that the bottom surface of the conveyer belt 101 can be effectively protected, the conveyer belt 101 is prevented from being scratched, and the service life is prolonged.

In the prior art, a cleaning machine sprays or soaks glass, then brushes the surface of the glass completely, then a sponge roller absorbs water on the surface of the glass, and finally the glass is dried; the drying speed is difficult to control, the glass can not be dried after the transmission speed is high, the efficiency is low due to the low transmission speed of the glass, and the energy consumption is high. Because the former process must dry printing ink completely just can wash, consequently, toast required temperature height, glass's temperature is also relatively higher, it is long to wash the required time of cooling, inefficiency, and the brush hair on the brush can be attached to the glass surface during washing, cause the influence to the cleanness on glass surface, the glass surface after this kind of cleaning machine washing cooling is in the stoving in addition remains water stain easily, influence the printing effect, be unfavorable for improving glass printing efficiency, brush and sponge roller all belong to quick consumables in the cleaning machine among the prior art in addition, life-span about half a year on average, use cost is high. In addition, the cleaning machine needs to wash the glass with water, scrub the brush, dry etc., the power is up to 12-15kw, the power consumption is high, therefore the use cost is high, in addition, brush and sponge roller all belong to fast consumables, about half a year life-span on average, with high costs, compared with prior art, the apparatus cost of this application only needs to carry on the water-cooling or cooperate with the air-cooling to cool down, the power is as low as about 4kw, the power consumption is low, only transport belt 101 and sponge belong to consumables in addition, the cost is lower; the invention does not need to soak, clean and dry the glass, effectively avoids water stains and improves the printing quality of the glass.

In addition, the prior art cleaning machine is only washed by cold water, no cooling system is provided, the temperature of cleaning water can be gradually increased, the water also absorbs heat and evaporates, the evaporation capacity is large, and therefore water needs to be changed frequently or added with water.

Further, gaps are arranged between the periphery of the water cooling table 212 and the side wall of the water cooling groove 211. Specifically, in this embodiment, the water cooling table 212 is provided with the clearance with the lateral wall of water cooling recess 211 all around for water cooling recess 211 is cyclic annular around water cooling table 212, the cooling water that gushes out from apopore 214 of water cooling table 212 will flow toward the direction of water cooling recess 211 all around under the action of gravity, the cooling water that gets into water cooling recess 211 accomplishes the hydrologic cycle through circulative cooling subassembly 220, it cools off again to guarantee that the cooling water gets into circulative cooling subassembly 220 after with the heat transfer of conveyer belt 101, guarantee cooling efficiency.

Further, the top surface of the water cooling tank 210 is further provided with two fence plates 215, the two fence plates 215 are respectively arranged on the left side and the right side of the top surface of the water cooling tank 210, and the top ends of the fence plates 215 are higher than the top surface of the water cooling tank 210. Specifically, in this embodiment, the top end of the fence plate 215 is higher than the top surface of the water cooling tank 210, and the fence plate 215 can further fence the cooling water, so as to prevent the cooling water from overflowing from the water cooling groove 211.

Further, the front end and the rear end of the top surface of the water cooling tank 210 are respectively provided with a wiper strip 216. Specifically, the wiping strip 216 is made of rubber materials, has elasticity and has a water retaining effect, cooling water in the water-cooling groove 211 can be prevented from overflowing from the front end and the rear end, the wiping effect can also be achieved, the wiping strip 216 at the front end can be located, water at the bottom of the conveying belt 101 can be wiped out, cooling water flows back to the water-cooling groove 211, and the problem that the cooling water is conveyed out by the conveying belt 101 is avoided.

Further, the circulation cooling module 220 includes a circulation water tank 221, a circulation water pump 222 and a heat exchanger 223; a water return port 2111 is formed in the bottom of the water collecting tank 215; the water return port 2111 is connected with the circulating water tank 221 through a water pipe; the input end of the circulating water pump 222 is connected with the circulating water tank 221, the output end of the circulating water pump 222 is connected with the water storage cavity of the water cooling tank, and the cooling pipe of the heat exchanger 223 is arranged inside the circulating water tank 221; the water outlet area of the water return port 2111 is at least twice the total water outlet area of the water outlet holes 214.

Specifically, the cooling water after absorbing heat overflows from the cavity surrounded by the water baffle 218 and flows into the water cooling groove 211 outside the water baffle 218, under the action of gravity, the cooling water in the water cooling groove 211 outside the water baffle 218 flows back into the circulation water tank 221 from the water return port 2111, the cooling pipe of the heat exchanger 222 extends into the circulation water tank 221, the heat exchanger 222 performs heat exchange cooling on the cooling water after absorbing heat in the circulation water tank 221, so that the water temperature in the circulation water tank 221 is reduced to a temperature capable of being used for cooling, under the water pumping pressure of the circulation water pump 221, the cooling water in the circulation water tank 221 is output into the water storage cavity 213 of the water cooling tank 210 and then flows out from the water outlet hole 214, and is recycled to cool the transportation belt 101 and the glass, so that the cooling water for cooling the transportation belt 101 and the glass is in a low-temperature state, the cooling efficiency of the glass is ensured, and the arrangement of the circulation water tank 221 can avoid the problem that the circulation water pump 221 directly pumps air when the cooling water is pumped from the water cooling groove 211, so that redundant air is input into the water storage cavity 213 and the cooling effect is affected.

Further, a transport driving assembly is connected to the transport belt 101, the transport driving assembly includes two rotating shafts 102 and a driving member, and the transport belt 101 is wound around the outer side surfaces of the two rotating shafts 102; the driving piece is used for driving the rotating shaft 102 to rotate, so that the conveying belt 101 is driven to convey glass; the top surface of the water cooling table 212 abuts against the bottom surface of the conveyor belt 101.

Specifically, the driving part is sleeved on the two rotating shafts 102 correspondingly on two sides of the conveyer belt 101, and the motor drives one of the rotating shafts 102 to rotate, so that the conveyer belt 101 is driven to rotate around the two rotating shafts 102 to transmit, the glass on the conveyer belt 101 is conveyed forwards, the conveyer belt 101 is in contact with the protruding strips 212 in motion, and the heat of the glass is absorbed through the protruding strips 212 under the effect of heat exchange, so that the glass cooling efficiency is improved.

Further, the conveyer belt 101 is a Teflon conveyer belt, and the thickness of the conveyer belt 101 is 0.1 mm-2 mm. In the embodiment, the Teflon conveyor belt can work in the temperature environment of-70 ℃ to +260 ℃, and has weather resistance and ageing resistance. Has the advantages of chemical corrosion resistance, and resistance to corrosion of strong acid, strong alkali, aqua regia and various organic agents. Fire-proof, fire-retardant and good air permeability. The adhesive is not easy to adhere to any substance and is easy to clean; under high load, the wear-resisting property is excellent. Good dimensional stability (the elongation coefficient is less than 5 per mill) and high strength. Thereby being beneficial to bearing high-temperature glass; the thickness of the conveyer belt 101 is 0.1 mm-2 mm, so that the support of the glass can be ensured, the temperature transfer rate is ensured, and the cooling efficiency of the glass is improved.

Further, an insulating layer 218 is disposed on the periphery of the side surface of the water cooling tank 210, and the insulating layer 218 is used for maintaining the water temperature of the water cooling tank 210. Specifically, in this embodiment, specifically, the insulating layer 218 may play a role in blocking and slowing down heat exchange between cooling water inside the water cooling tank 210 and air outside the water cooling tank 210, and may keep the water temperature of the water cooling tank 210 in a low temperature state, where most of the heat exchange is performed between the top surface of the water cooling tank 210 and the water cooling platform 212 and the cooling water, so as to ensure the cooling efficiency of the cooling water.

Preferably, a plurality of flow guide strips 219 are arranged on the top surface of the water cooling table 212; the flow guide strips 219 are arranged in a protruding manner from the top surface of the water cooling platform 212, the plurality of flow guide strips 219 are arranged on the water cooling platform 212, the water outlet hole 214 is generally arranged between the two flow guide strips 219, and one or more water outlets 214 are arranged between the two flow guide strips 219 to ensure that the space between the adjacent flow guide strips 219 is filled with cooling water; can make the top surface distribution at water cooling table 212 of the cooling water that gushes out from apopore 214 more even to make glass panel cooling more even, guarantee the cooling effect to glass panel.

Other configurations and operations of a transfer device for glass cooling according to embodiments of the present invention are known to those of ordinary skill in the art and will not be described in detail herein.

In the description herein, references to the description of the terms "embodiment," "example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims (10)

1. A transfer device for glass cooling, characterized by: comprises a conveying belt and a water cooling mechanism; the water cooling mechanism comprises a water cooling tank and a circulating cooling assembly;

the top surface of the water cooling tank is provided with a water cooling groove in a downward concave manner, and the middle part of the water cooling groove is provided with a water cooling platform in a protruding manner;

a water storage cavity is formed in the water cooling tank, a plurality of water outlet holes are formed in the top surface of the water cooling platform, the water outlet holes are communicated with the outside air and the water storage cavity, and cooling water in the water storage cavity is flushed out of the water outlet holes so as to cool the conveying belt;

the input end of the circulating cooling component is communicated with the water cooling groove, and the output end of the circulating cooling component is communicated with the water storage cavity;

the conveying belt is arranged above the water cooling mechanism and is impervious, and the bottom surface of the conveying belt is pressed against the top surface of the water cooling table and is conveyed forwards.

2. A transfer device for glass cooling according to claim 1, characterized in that: the top surface of the water cooling platform is not lower than the top surface of the water cooling tank; the width of the conveyer belt is larger than that of the water cooling table and smaller than that of the top surface of the water cooling tank.

3. The transfer device for glass cooling according to claim 1, wherein: gaps are arranged between the periphery of the water cooling table and the side wall of the water cooling groove.

4. The circulating water cooled transfer device of claim 1, wherein: the top surface of water cooling box still is provided with two fencing boards, two the fencing board set up respectively in the both sides of the top surface of water cooling box.

5. A transfer device for glass cooling according to claim 1, characterized in that: and the front end and the rear end of the top surface of the water cooling tank are respectively provided with a water scraping strip.

6. The transfer device for glass cooling according to claim 1, wherein: the circulating cooling assembly comprises a circulating water tank, a circulating water pump and a heat exchanger; a water return port is formed in the bottom of the water collecting tank;

the water return port is connected with the circulating water tank through a water pipe; the input end of the circulating water pump is connected with the circulating water tank, the output end of the circulating water pump is connected with the water storage cavity of the water cooling tank, and the cooling pipe of the heat exchanger is arranged in the circulating water tank.

7. A transfer device for glass cooling according to claim 1, characterized in that: the conveying belt is connected with a conveying driving assembly, the conveying driving assembly comprises two rotating shafts and a driving piece, and the conveying belt is wound on the outer side surfaces of the two rotating shafts; the driving piece is used for driving the rotating shaft to rotate so as to drive the conveying belt to convey glass; the top surface of the water cooling table is abutted against the bottom surface of the conveying belt.

8. A transfer device for glass cooling according to claim 7, characterized in that: the conveyer belt is a Teflon conveyer belt, and the thickness of the conveyer belt is 0.1 mm-2 mm.

9. The transfer device for glass cooling according to claim 1, wherein: the side periphery of the water cooling tank is provided with a heat preservation layer, and the heat preservation layer is used for keeping the water temperature of the water cooling tank.

10. A transfer device for glass cooling according to claim 1, characterized in that: the top surface of the water cooling table is provided with a plurality of flow guide strips.

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