CN108995384B - Ink heating and drying structure and printer applying same - Google Patents

Abstract

An ink heating and drying structure and a printer using the same are provided. The utility model provides an ink heating drying structure, includes infrared heating device, is used for through the mode of sweeping gas with the first device of blowing of the even dispersion of heat that infrared heating device emitted, is used for providing the heat transmission device of heat and the device that shelters from that is used for sheltering from the infrared light that infrared heating device emitted to first device of blowing. The infrared heating device controls the infrared light emitted by the infrared heating device through the shielding device, the shielding piece is moved to open the shielding device when ink needs to be heated, the infrared light irradiates on the product to evaporate the ink, and the shielding piece is moved again to close the shielding device when the ink does not need to be heated, so that the infrared light cannot penetrate through the shielding device to irradiate on the product, and the product is prevented from being damaged by lasting high-temperature heating.

Description

Ink heating and drying structure and printer applying same

Technical Field

The invention relates to the technical field of printing, in particular to an ink heating and drying structure and a printer applying the same.

Background

The spray drawing machine is a series of products of printer, and is characterized by that it utilizes special ink to print various patterns on the glass, then utilizes tempering and sintering process to permanently combine the patterns with glass. And when the glass is printed, oily ink is used, but the glass is of a smooth structure, and when the oily ink is printed on the glass, the ink is scattered, so that the printing effect is poor. Therefore, the ink is heated and dried, so that the ink drops are solidified on a smooth medium such as glass more quickly.

Disclosure of Invention

The invention aims to provide an ink heating and drying structure and a printer applying the same, which can quickly and uniformly evaporate a solvent in ink on a product and avoid influence on a printing effect caused by ink blooming.

An ink heating and drying structure comprises an infrared heating device;

the first air blowing device is used for uniformly dispersing the waste heat of the infrared heating device in a gas blowing mode;

the heat transmission device is used for supplying heat to the first blowing device;

the shielding device is used for shielding the infrared light emitted by the infrared heating device;

the shielding device comprises a shell and a shielding piece arranged on the shell in a sliding mode, and the effect of shielding infrared light is controlled by moving the shielding piece;

the heat transmission device and the first blowing device are arranged in the shell.

The first air blowing device is arranged, and the heat is driven to be transferred through the air flow, so that the temperature distribution on the product is more uniform, and the ink evaporation on the product is facilitated. And come for first blowing the device through heat transmission device and provide the heat for the temperature of the gas of spouting out from first blowing the device is higher, at first avoids gas temperature to hang down and slows down the evaporation rate of ink, secondly, can also avoid product or infrared heating device (the inside is provided with the infrared lamp) to be broken because the sudden cold and sudden hot of gas. Finally, the infrared light emitted by the infrared heating device is controlled by the shielding device, the shielding piece is moved to open the shielding device when the ink needs to be heated, the infrared light irradiates on the product to evaporate the ink, and when the ink does not need to be heated, the shielding piece can be moved again to close the shielding device, so that the infrared light cannot penetrate through the shielding device to irradiate on the product, and the product is prevented from being damaged by high-temperature heating for a long time.

Preferably, the shielding device further comprises a driving device for driving the shielding piece to move, and the driving device is arranged on the shell. More preferably, the driving device is a cylinder, a motor or an engine.

Preferably, the shielding device comprises a fixing part matched with the shielding part, the fixing part and the shielding part are both provided with cavities, when the infrared light does not need to be shielded, the fixing part and the shielding part are mutually overlapped, the infrared light penetrates through the cavities to shine out, when the infrared light needs to be shielded, the fixing part and the shielding part are staggered mutually, and the shielding part and the fixing part mutually shield the cavities of the other side, so that the infrared light is shielded.

In order to improve the space utilization rate of the whole device and enable the internal equipment to be placed more compactly, the fixing piece and the shielding piece are arranged, and can be mutually overlapped when shielding is not needed, so that the occupied space is reduced. It will be appreciated that the shielding means may be of helical blade construction in addition to the above-described construction.

Preferably, the heat transfer device is connected with the first blowing device through a pipeline, and the heat transfer device is used for supplying heat to the first blowing device by transferring heated gas to the first blowing device.

Because the shielding device adopts a structure combining the fixing piece and the shielding piece, when infrared light irradiates on a product, the fixing piece can block part of the infrared light, so that the product is uneven in heating and easy to break; and secondly, the heat is transferred by the air flow, so that the temperature distribution on the product is more uniform, and the uneven heating of the product is avoided.

Preferably, the heat transfer device is provided with a gas inlet (the gas inlet is connected with a positive pressure gas source) and a gas outlet, and the gas inside the heat transfer device is heated by the heat emitted by the infrared heating device.

Because the infrared heating device can radiate heat in all directions, and part of the heat in the direction can not be transferred to the product to cause waste, the invention heats the gas in the heat transmission device by arranging the heat transmission device beside the infrared heating device, and then the heat transmission device transmits the gas to the first blowing device. It should be understood that the heat transfer device is used to supply heat to the first blowing device by transferring the gas with higher temperature to the first blowing device, and the heat transfer device can also achieve the above effect by other means, such as the heat transfer device is a heater, and directly heats the gas in the first blowing device.

Preferably, the ink heating and drying structure further comprises more than one heat transfer device.

One end of the first heat transmission device receives air from a positive pressure air source, the air is heated and mixed and then is transmitted to the second heat transmission device through the other end to be heated continuously, and finally the air of the second heat transmission device is transmitted to the first blowing device to be blown out under the action of positive pressure. It should be understood that besides the above-mentioned solution can achieve the effect of uniform gas mixing, the heat transfer device can also supply gas to the first blowing device in a rotating manner, so as to ensure the storage time of the gas in the heat transfer device and improve the degree of gas mixing.

The infrared heating device comprises a bracket and an infrared lamp arranged on the bracket, and the bracket is arranged in the shell; more preferably, the housing surrounds the periphery of the infrared lamp and is provided with a notch, infrared rays emitted by the infrared heating device penetrate through the notch to irradiate on a product, and the shielding piece is arranged at the notch.

According to the invention, the shell is arranged and surrounds the periphery of the infrared lamp, so that the energy loss of the infrared lamp is avoided, the heat can be irradiated on the product through the gap more intensively, and the ink evaporation speed is accelerated.

More preferably, the housing is provided with a plurality of vent holes.

Preferably, the first blowing device is provided with at least one ventilation slit.

The first air blowing device sprays the air from the heat transfer device through the air permeable seam, so that the infrared heating device heats more uniformly.

Preferably, the ink heating and drying structure further includes a second air blowing device for keeping the temperature constant while preventing heat from being diffused.

Preferably, the heat transmission device is arranged between the second blowing device and the infrared heating device, and the gas blown by the second blowing device passes through the heat transmission device and is heated by the heat transmission device and then flows to the infrared heating device.

According to the invention, the high-temperature outer wall of the heat transmission device exchanges heat with the gas of the second blowing device, so that after the temperature of the gas is increased, the gas flows to the infrared heating device, and the heat emitted by the infrared heating device is uniformly dispersed. It should be understood that the present solution can also achieve the above effect by arranging a heat exchange pipe inside the heat transport device to exchange heat between the gas blown out from the second blowing device and the gas in the heat transport device.

A printer comprises the ink heating and drying structure.

The present invention is advantageous over other configurations.

(1) The first air blowing device is arranged, and the heat is driven to be transferred through the air flow, so that the temperature distribution on the product is more uniform, and the ink evaporation on the product is facilitated.

(2) Avoid the sudden cooling and sudden heating caused by uneven gas temperature, and protect the product and the infrared heating device (namely the infrared lamp).

(3) In addition, through various heat exchange and heat storage modes, the loss of energy is effectively reduced, and the utilization rate of the energy is improved.

Drawings

Fig. 1 is an exploded view of the present invention.

Fig. 2 is a schematic structural diagram of the present invention.

Fig. 3 is a schematic structural diagram of the heat transfer device and the first blowing device.

Fig. 4 is a schematic structural diagram of an infrared heating device.

FIG. 5 is a schematic view of the structure of the present invention (with a second air blowing device).

Fig. 6 is a schematic structural diagram of the first blowing device and the heat transport device.

The attached drawings are as follows: 1. an infrared heating device; 11. an infrared lamp; 12. a support; 2. a first blowing device; 21. a gas-permeable seam; 3. a heat transfer device; 4. a shielding device; 41. a housing; 42. a shield; 43. a fixing member; 5. and a second blowing device.

Detailed Description

The invention will be further illustrated with reference to the following specific examples. It should be understood that these examples are for illustrative purposes only and are not intended to limit the scope of the present invention. Further, it should be understood that various changes or modifications of the present invention may be made by those skilled in the art after reading the teaching of the present invention, and such equivalents may fall within the scope of the present invention as defined in the appended claims.

As shown in fig. 1 and 2, an ink heating and drying structure includes an infrared heating device 1;

the first air blowing device 2 is used for uniformly dispersing the waste heat of the infrared heating device in a gas spraying mode;

a heat transfer device 3 for supplying the gas heated by the infrared heating device 1 to the first blowing device 2;

a shielding device 4 for shielding the infrared light emitted from the infrared heating device 1;

the shielding device 4 comprises a housing 41 and a shielding member 42 slidably disposed on the housing 41, and the effect of shielding infrared light is controlled by moving the shielding member 42.

The heat transfer device 3 and the first blowing device 2 are arranged in the housing 41.

The first air blowing device 2 is arranged, and heat is driven to be transferred through air flow, so that the temperature distribution on the product is more uniform, and the ink on the product is favorably evaporated and dried. And come for first device 2 of blowing to provide heat through heat transfer device 3 for the temperature of the gas of spouting from first device 2 of blowing is higher, avoids gas temperature at first to hang down and slows down the evaporation rate of ink, and secondly, can also avoid product or infrared heating device 1 (built-in infrared lamp 11) to be broken because the sudden cold and sudden hot of gas.

Preferably, the shutter device 4 further comprises a drive device for moving the shutter 42, the drive device being provided on the housing. More preferably, the driving device is a cylinder, a motor or an engine.

Preferably, the shielding device 4 includes a fixing member 43 matching with the shielding member 42, and both the fixing member 43 and the shielding member 42 are provided with cavities, when the infrared light does not need to be shielded, the fixing member 43 and the shielding member 42 overlap each other, the infrared light irradiates through the cavities, when the infrared light needs to be shielded, the fixing member 43 and the shielding member 42 are staggered with each other, and the shielding member 42 and the fixing member 43 shield the cavities of the other, so that the infrared light is shielded.

Preferably, the heat transmission device 3 is connected with the first blowing device 2 through a pipeline, and the heat transmission device 3 supplies heat to the first blowing device 2 by transmitting heated gas to the first blowing device 2.

Preferably, as shown in fig. 3, the heat transport device 3 is provided with a gas inlet and a gas outlet, and heats the gas inside the heat transport device 3 by the heat emitted from the infrared heating device 1, wherein the gas inlet is connected with a positive pressure gas source.

In the embodiment, the heat transmission device 3 is arranged and the heat transmission device 3 is arranged beside the infrared heating device 1, the gas in the heat transmission device 3 is heated by the infrared heating device 1, and the gas is transmitted to the first blowing device 2 by the heat transmission device 3. It should be understood that in other embodiments, the heat transfer device 3 can provide heat for the first blowing device 2 by transferring gas with higher temperature to the first blowing device 2, and the above effect can also be achieved by other means, such as the heat transfer device 3 is a heater, and directly heats the gas in the first blowing device 2.

Preferably, the ink heating and drying structure further comprises more than one heat transfer device 3.

One end of the first heat transmission device 3 receives air from a positive pressure air source, the air is heated and mixed and then is transmitted to the second heat transmission device 3 through the other end to be heated continuously, and finally the air of the second heat transmission device 3 is transmitted to the first blowing device 2 under the action of positive pressure and then is blown out.

As shown in fig. 4, the infrared heating device 1 includes a plate-shaped bracket 12 and an infrared lamp 11 disposed on the bracket 12, the bracket is disposed in a housing, the housing surrounds the periphery of the infrared lamp and has a notch at a lower portion, and the shielding member is disposed at the notch.

More preferably, the housing 41 is provided with a plurality of vent holes.

As shown in fig. 6, the first blowing device 2 is preferably provided with at least one gas permeable slit 21, and the first blowing device 2 is also provided with a gas inlet for receiving gas from the heat transfer device 3.

The first air blowing device 2 sprays the air from the heat transmission device 3 through the air permeable seam 21, so that the residual heat of the infrared heating device is uniformly dispersed.

Preferably, as shown in fig. 5, the ink heating and drying structure further includes a second air blowing device 5, and the heat transport device 3 is configured to provide heat to the air blown by the second air blowing device 5.

Preferably, the second blowing device 5, the heat transmission device 3 and the infrared heating device 1 are sequentially installed from top to bottom, and the gas blown by the second blowing device 5 passes through the heat transmission device 3 and is heated by the heat transmission device 3 and then goes to the infrared heating device 1. The second air blowing device 5 can be a fan, an air blower, a compressor and the like.

The second blowing device 5 is arranged above the shell 41, the shell 41 is provided with a vent hole for the gas of the second blowing device 5 to flow through, the gas is blown downwards under the action of the second blowing device 5 and passes through the vent hole to reach the heat transmission device 3 to cool the heat transmission device 3 and the infrared heating device 1.

Preferably, the infrared heating device 1 further comprises an infrared lamp 11 shutter disposed below the housing 41, and the infrared lamp 11 shutter is turned off to block infrared light for the object of the ink heating and drying structure.

A printer comprises the ink heating and drying structure.

When the printer carries out air brushing and printing, the infrared lamp 11 is always turned on (to avoid frequent turning on and off and damage), and when the infrared lamp 11 is needed to heat a product, firstly, the driving device drives the shielding piece 42 to move, so that the shielding piece 42 and the fixing piece 43 are mutually overlapped, and infrared light is emitted through the cavity.

The air of positive pressure air supply is gone into first heat transfer device 3 through the air inlet pump of first heat transfer device 3, the air is through the infrared heating back temperature rise of closely, the air rethread pump is into second heat transfer device 3, then the air of heating is carried in first air blowing device 2 from second heat transfer device 3, the air permeability seam 21 of hot-air through first air blowing device 2 goes out, the flow of the external air of disorder, make the heating more even, new air also can constantly be gone into to first heat transfer device 3 simultaneously, heat the air.

When the infrared lamp 11 is not needed to heat the product, the driving device drives the shielding piece 42 to move, so that the fixing piece 43 and the shielding piece 42 are staggered with each other, the shielding piece 42 and the fixing piece 43 shield the cavity of the other side, and infrared light cannot be radiated out through the cavity. At the same time, the heat transport device 3 no longer supplies air to the first blowing device 2, and the first heat transport device 3 continues to heat the air inside by means of the infrared lamp 11.

And a second air blowing device 5 (a fan in the embodiment) is arranged above the infrared lamp 11, and the second air blowing device 5 continuously blows air to the infrared lamp 11 below to cool the equipment below the second air blowing device 5, so as to avoid over-high temperature.

It should be understood that the above-described embodiments of the present invention are merely examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (7)

1. An ink heating and drying structure, comprising:

an infrared heating device (1);

the first blowing device (2) is used for uniformly dispersing heat emitted by the infrared heating device in a blowing gas mode;

the heat transmission device (3) is used for supplying heat to the first blowing device (2);

the shielding device is used for shielding the infrared light emitted by the infrared heating device;

the shielding device comprises a shell (41), a shielding piece arranged on the shell (41) in a sliding mode and a fixing piece (43) matched with the shielding piece (42), wherein cavities are formed in the fixing piece (43) and the shielding piece (42), the effect of shielding infrared light is controlled by moving the shielding piece, when the fixing piece (43) and the shielding piece (42) are mutually overlapped, the infrared light penetrates through the cavities to be irradiated, and when the fixing piece (43) and the shielding piece (42) are mutually staggered, the shielding piece (42) and the fixing piece (43) mutually shield the cavities of the other side, so that the infrared light is shielded;

the heat transmission device (3) and the first air blowing device (2) are arranged in the shell (41); the heat transmission device (3) is connected with the first blowing device (2) through a pipeline, and the heat transmission device (3) transmits heated gas to the first blowing device (2) to provide heat for the first blowing device (2); the heat transmission device (3) is provided with a gas inlet and a gas outlet, and heats the gas in the heat transmission device (3) through the heat emitted by the infrared heating device (1).

2. An ink heating and drying structure according to claim 1, wherein the shutter means further comprises drive means for moving the shutter member, the drive means being provided on the housing (41).

3. An ink heating and drying structure according to claim 1, further comprising more than one heat transfer means (3).

4. The ink heating and drying structure according to claim 1, wherein the infrared heating device (1) comprises a bracket (12) and an infrared lamp (11) arranged on the bracket (12), the bracket (12) is arranged in a housing (41), the housing (41) surrounds the infrared lamp (11) and is provided with a notch, and the shielding member (42) is arranged at the notch.

5. An ink heating and drying structure according to claim 1, further comprising a second air blowing means (5), said second air blowing means (5) being provided on the casing (41).

6. An ink heating and drying structure as claimed in claim 5, wherein the heat transfer device (3) is disposed between the second blowing device (5) and the infrared heating device (1), and the air blown by the second blowing device (5) passes through the heat transfer device (3) and then goes to the infrared heating device (1).

7. A printer comprising an ink heat drying structure as claimed in any one of claims 1 to 6.

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