CN212171684U - Ceramic ink transfer device - Google Patents

Abstract

The utility model discloses a ceramic ink transfer device, which comprises a supporting platform, a ceramic ink transfer cylinder, an ink feeding pipeline, an ink discharging pipeline, an ink pump, an ink supplying pipeline, an ink path system of an ink-jet printer and a return pipeline; the ceramic ink transfer cylinder is arranged on the supporting platform, the ink feeding pipeline is connected with the ceramic ink transfer cylinder, the ceramic ink transfer cylinder is connected with one end of the ink discharging pipeline, the other end of the ink discharging pipeline is connected with the ink pump, the ink pump is connected with one end of the ink supplying pipeline, and the other end of the ink supplying pipeline is connected with the ink path system of the ink jet printer; the ink pump is also connected with one end of a return pipeline, and the other end of the return pipeline is connected with the ceramic ink transfer cylinder. Adopt the utility model discloses, make ink storage device recoverable, reduce ink jet equipment use cost, reduce the environmental pollution that abandonment ink storage device caused.

Description

Ceramic ink transfer device

Technical Field

The utility model relates to an ink jet equipment especially relates to a pottery ink transfer device.

Background

Ceramics generally require ink jet processing using ink jet equipment during the manufacturing process. The comparison document (publication number: CN207842381U) discloses a ceramic glaze high-definition printing ink-jet device, which comprises a supporting table, a control cabinet and an ink-jet frame, wherein supporting plates are arranged on two sides of the lower end of the supporting table, the control cabinet is arranged in the middle of the supporting plate, an operating plate is arranged on one side wall of the control cabinet, a conveying belt is arranged at the upper end in the supporting table, a fixing block is arranged at the upper end of the conveying belt, a driving wheel is arranged at one end in the conveying belt, a belt wheel II is arranged in the middle of the side wall of the driving wheel I, a belt is arranged on the periphery of the belt wheel, the ink-jet frame is arranged in the middle of the upper end of the supporting table, a welding plate, an ink. Adopt above-mentioned equipment, the simple operation through setting up the operation panel, can detect the process of printing constantly, is favorable to improving printing efficiency, through setting up the steerable inkjet speed of china ink valve, can guarantee the quality of printing.

However, the existing waste ink storage equipment such as ink cartridges, ink bottles and tanks is not recovered by a special mechanism, so that the waste rate is high, and the problems of high use cost and environmental pollution of the ink jet equipment are caused.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that improve current ink storage equipment for ink storage equipment is recoverable, reduces ink jet equipment use cost, reduces the environmental pollution that abandonment ink storage equipment caused.

In order to solve the technical problem, the utility model provides a ceramic ink transfer device, which comprises a supporting platform, a ceramic ink transfer cylinder, an ink feeding pipeline, an ink discharging pipeline, an ink pump, an ink supplying pipeline, an ink path system of an ink-jet printer and a return pipeline; the ceramic ink transfer cylinder is arranged on the supporting platform, the ink feeding pipeline is connected with the ceramic ink transfer cylinder, the ceramic ink transfer cylinder is connected with one end of the ink discharging pipeline, the other end of the ink discharging pipeline is connected with the ink pump, the ink pump is connected with one end of the ink supplying pipeline, and the other end of the ink supplying pipeline is connected with the ink path system of the ink jet printer; the ink pump is also connected with one end of a return pipeline, and the other end of the return pipeline is connected with the ceramic ink transfer cylinder.

As an improvement of the scheme, the ceramic ink tank further comprises a motor and a stirring paddle, wherein the stirring paddle is installed on the motor, the motor is arranged at the top of the ceramic ink rotary cylinder, and the stirring paddle is placed at the bottom of the ceramic ink rotary cylinder.

As an improvement of the scheme, the ink supply device further comprises a filtering device, wherein the ink pump is connected with the filtering device, the filtering device is connected with one end of the ink supply pipeline, and the other end of the ink supply pipeline is connected with an ink path system of the ink jet printer; the filter device is also connected with one end of a return pipeline, and the other end of the return pipeline is connected with the ceramic ink transfer cylinder.

As an improvement of the above scheme, the ink jet printing ink system further comprises a compressed air device and a compressed air source pipeline, wherein the ink pump is a pneumatic diaphragm pump, the compressed air device is connected with the compressed air source pipeline, and the compressed air source pipeline is connected with the pneumatic diaphragm pump.

As an improvement of the scheme, the front end of the pneumatic diaphragm pump is provided with a mounting valve.

As an improvement of the scheme, the motor adopts a pneumatic motor, the compressed air device is connected with a compressed air source pipeline, and the compressed air source pipeline is connected with the pneumatic motor.

As the improvement of the proposal, the device also comprises an ink supply valve and a return valve; the ink supply pipeline is connected with an ink supply valve, the ink supply valve is connected with an ink path system of the ink-jet printer, the backflow pipeline is connected with a backflow valve, and the backflow valve is connected with the ceramic ink transfer cylinder.

As an improvement of the scheme, the device further comprises a gravity sensor, and the gravity sensor is installed between the ceramic ink rotary cylinder and the supporting platform.

As an improvement of the scheme, the device also comprises a feeding valve and a discharging valve; the feeding valve is installed at the feeding hole of the ceramic ink rotary cylinder, the feeding hole is connected with the ink feeding pipeline through the feeding valve, the discharging valve is installed at the discharging hole of the ceramic ink rotary cylinder, and the discharging hole is connected with the ink discharging pipeline through the discharging valve port.

As the improvement of the scheme, the top end of the ceramic ink transfer cylinder is provided with an air vent, and the outside of the air vent is wrapped with a filter screen.

Implement the utility model has the advantages that:

implement the utility model discloses ceramic ink transfer device for ink storage device is recoverable, reduces ink jet equipment use cost, reduces the environmental pollution that abandonment ink storage device caused.

Specifically, all inks of the ceramic ink jet apparatus are stored and transported by the ceramic ink transfer cylinder. The ceramic ink rotary cylinder is filled with ink through an ink feeding pipeline, then the ink is conveyed to an ink path system of the ink-jet printer through an ink discharging pipeline and an ink pump, so that the ink is supplied to the ink-jet printer in real time, and meanwhile, part of the ink flows back to the ceramic ink rotary cylinder from a return pipeline. Because the ceramic ink transfer cylinder can be recycled, the ink packaging tank and the packaging box are saved, the resources are greatly saved, the use cost of the ink-jet printer is reduced, and the environmental pollution is reduced.

Furthermore, the ceramic ink transfer cylinder also comprises a motor and a stirring paddle, and the stirring paddle is driven by the motor to stir ink so that the ink is always in a flowing state, the operation of shaking up the ink is saved, and the influence of color difference caused by using different ink batches is reduced.

Drawings

FIG. 1 is a schematic structural view of a first embodiment of a ceramic ink transfer device according to the present invention;

FIG. 2 is a schematic view of a first embodiment of the ceramic ink transfer device of the present invention;

FIG. 3 is a schematic structural view of a second embodiment of the ceramic ink transfer device of the present invention;

FIG. 4 is a schematic view of the ink flow direction of a second embodiment of the ceramic ink transfer device of the present invention;

FIG. 5 is a schematic view of the ink flow direction of an inkjet printer according to a second embodiment of the present invention;

FIG. 6 is a schematic view of the ink flow direction of an ink jet printer according to a second embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the present invention will be described in further detail with reference to the accompanying drawings. It is only noted that the invention is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the invention.

Fig. 1 shows the structure schematic diagram of the first embodiment of the ceramic ink transfer device of the present invention, which comprises a supporting platform 1, a ceramic ink transfer cylinder 2, an ink feeding pipeline 3, an ink discharging pipeline 4, an ink pump 5, an ink supplying pipeline 6, an ink path system 7 of an ink jet printer and a backflow pipeline 8.

The ceramic ink inverting cylinder 2 is mounted on a support platform 1. The ink feed pipe 3 is connected to the ceramic ink rotary cylinder 2. The ceramic ink rotary cylinder 2 is connected with one end of an ink discharging pipeline 4, and the other end of the ink discharging pipeline 4 is connected with an ink pump 5. The ink pump 5 is connected to one end of the ink supply pipe 6. The other end of the ink supply pipe 6 is connected to an ink path system 7 of the ink jet printer.

The ink pump 5 is also connected with one end of a return pipeline 8, and the other end of the return pipeline 8 is connected with the ceramic ink transfer cylinder 2.

It should be noted that, in the first embodiment of fig. 1, the ink pump 5 is connected to the ink supply pipe 6 and the return pipe 8 through a section of pipe, and the three pipes may be connected through a three-way valve, or may be connected through other methods, such as an integrally formed method.

All inks of the ceramic ink jet apparatus are stored and transported by the ceramic ink inverting cylinder 2. The ceramic ink rotary cylinder 2 is filled with ink through an ink feeding pipeline 3, then the ink passes through an ink discharging pipeline 4, the ink is pressurized by an ink pump 5, and the ink is transmitted to an ink path system 7 of the ink-jet printer through an ink supplying pipeline 6, so that the ink is supplied to the ink-jet printer in real time. While part of the ink flows from the return conduit 8 back to the ceramic ink rotary cylinder 2. Because the ceramic ink rotary cylinder 2 can be repeatedly recycled, the use of an ink packaging tank and a packaging box is omitted, the resources are greatly saved, the use cost of the ink-jet printer is reduced, and the environmental pollution is reduced.

Preferably, the support platform 1 is made of steel material. The ceramic ink rotary cylinder 2, the ink feeding pipeline 3, the ink discharging pipeline 4 and the backflow pipeline 8 are all made of food-grade 304 steel or food-grade 316 steel.

FIG. 2 is a schematic view showing the ink flow direction of the first embodiment of the ceramic ink transfer device of the present invention.

The ink is injected into the ceramic ink rotary cylinder 2 from the ink feeding pipeline 3, then flows out of the ceramic ink rotary cylinder 2, flows to the ink pump 5 through the ink discharging pipeline 4, is pressurized by the ink pump, and then flows to the ink path system 7 of the ink-jet printer through the ink supplying pipeline 6 for the printer to use, and flows back to the ceramic ink rotary cylinder 2 through the backflow pipeline 8.

Fig. 3 is a schematic structural view of a second embodiment of the ceramic ink transfer device according to the present invention, which is an improvement of the first embodiment, and the improvement point is specifically described below.

Further, still include motor 9 and stirring rake 10, stirring rake 10 is installed on motor 9, and motor 9 locates ceramic ink rotary cylinder 2 top to make the stirring rake place in ceramic ink rotary cylinder 2 bottom.

The ink is stirred by the stirring paddle 10 under the driving of the motor 9, so that the ink is always in a flowing state, the operation of shaking the ink uniformly is saved, and the influence of color difference caused by using different ink batches is reduced.

Preferably, the paddle 10 is made of food grade 304 steel or food grade 316 steel.

Further, a filter 11 is included, the ink pump 5 is connected to the filter 11, and the filter 11 is connected to one end of the ink supply pipe 6. The other end of the ink supply pipe 6 is connected to an ink path system 7 of the ink jet printer. The filter device is also connected with one end of a return pipeline, and the other end of the return pipeline is connected with the ceramic ink transfer cylinder 2.

It should be noted that, in the second embodiment of fig. 3, the filtering device 11 is specifically connected to the ink supply pipe 6 and the return pipe 8 through a section of pipe, and the three pipes may be connected through a three-way valve, or may be connected through other ways, such as an integrally formed way.

The filtering device 11 can filter the ink pressurized and output by the ink pump to remove impurities in the ink. Preferably, the filter device can use a filter element with a size of 10 microns or 20 microns.

Further, the ink jet printing machine further comprises a compressed air device 12 and a compressed air source pipeline 13, and the ink pump 6 is an air-operated diaphragm pump. The compressed air device 12 is connected with a compressed air source pipeline 13, and the compressed air source pipeline 13 is connected with the pneumatic diaphragm pump.

The pneumatic diaphragm pump has the advantages of reliable quality, long service life, low noise, small vibration and the like. The compressed air device compresses the outside air and transmits high-pressure air to the pneumatic diaphragm pump through a compressed air source pipeline, so that the diaphragm pump is driven to be started to pressurize ink. Preferably, a pneumatic diaphragm pump of the VA-20 type may be employed.

Further, the front end of the pneumatic diaphragm pump is provided with a mounting valve 14.

The valve 14 is installed to close the ink discharging pipe 4 in case of failure of the pneumatic diaphragm pump, so as to prevent ink leakage and facilitate the removal of the pneumatic diaphragm pump for maintenance.

Further, the motor 9 is a pneumatic motor, the compressed air device 12 is connected with a compressed air source pipeline 13, and the compressed air source pipeline 13 is connected with the pneumatic motor.

The pneumatic motor has the advantages of explosion-proof performance, wide rotating speed range, high starting torque, simple structure and the like. The compressed air device 12 pressurizes the ink by compressing the outside air and delivering high pressure air to the air operated diaphragm pump through the compressed air originating conduit 13, thereby driving the diaphragm pump.

Further, an ink supply valve 15 and a return valve 16 are included.

The ink supply pipe 6 is connected to an ink supply valve 15, and the ink supply valve 15 is connected to the ink path system 7 of the ink jet printer.

The return pipeline 8 is connected with a return valve 16, and the return valve 16 is connected with the ceramic ink transfer cylinder 2.

By the cooperation of the ink supply valve 15 and the return valve 16, the ink can be controlled to enter the ink path system 7 of the ink-jet printer through the ink supply pipe 15, and the ink can be controlled to flow back to the ceramic ink rotary cylinder 2 through the return pipe 8, so that different flow directions of the ink in the working state and the waiting state of the ink-jet printer can be controlled.

Further, a gravity sensor 17 is included. The gravity sensor 17 is installed between the ceramic ink rotary cylinder 2 and the support platform 1.

As shown in fig. 2, 4 gravity sensors 17 are symmetrically installed between the ceramic ink transfer cylinder 2 and the support platform 1 (there is a non-shown portion on the back of the ceramic ink transfer cylinder 2). The gravity sensor 17 can detect the weight of the rotary cylinder 2 in the ceramic ink, thereby calculating the amount of ink in the rotary cylinder 2 in the ceramic ink. Alternatively, the gravity sensor 17 may employ a2011 model load cell.

In addition, the ink feed pipe 3, the ink discharge pipe 4 and the return pipe 8 are connected with the ceramic ink transfer cylinder 2 by stainless steel hoses, so that the gravity sensor is not hindered in installation and detection.

Further, a feeding valve 18 and a discharging valve 19 are also included.

A feed valve 18 is installed at the feed port of the ceramic ink rotary cylinder 2. The feed port is connected to the ink feed pipe 3 through a feed valve 18.

The discharging valve 19 is arranged at the discharging port of the ceramic ink rotary cylinder 2, and the discharging port is connected with the ink discharging pipeline 4 through the discharging valve 19.

The feeding valve 18 and the discharging valve 19 are used in cooperation to inject and output the ink of the ceramic ink transfer cylinder 2, and can be closed when the ceramic ink transfer cylinder 2 is maintained so as to be convenient to disassemble.

Further, the top end of the ceramic ink transfer cylinder 2 is provided with an air vent, and the outside of the air vent is wrapped with a filter screen.

The air vent helps the circulation of air inside and outside the ceramic ink transfer cylinder 2, and the filter screen can prevent impurities in the outside air from entering the ceramic ink transfer cylinder 2 to pollute the ink.

The operation of the second embodiment of the ceramic ink transfer device of the present invention will be specifically described below.

When ink is replenished, the feed valve 18 is opened and the discharge valve 19 is closed. As shown in fig. 4, ink is poured into the ceramic ink rotary cylinder 2. And observing the detection data of the gravity sensor 17, stopping injecting the ink when the data to be detected reaches an upper limit value, such as 1000kg, and closing the feeding valve 18. At this time, the motor 9 is turned on to drive the stirring paddle 10 to slowly stir at a constant speed.

When the ink-jet printer does not need to use ink, the ink supply valve 15 is closed, and the discharge valve 19 and the return valve 16 are opened. As shown in fig. 5, the air operated diaphragm pump is turned on after the air compressing air unit 12 is turned on. After the ink slowly passes through the pneumatic diaphragm pump, the filtering device 11 and the backflow pipeline 8, the ink returns to the ceramic ink rotary cylinder 2 to form internal circulation. Meanwhile, the motor 9 drives the stirring paddle 10 to keep a slowly uniform stirring state in the ceramic ink transfer cylinder 2 all the time.

When the ink-jet printer needs to use ink, the return valve 16 is closed, and the discharge valve 19 and the ink supply valve 15 are opened. As shown in fig. 6, the air operated diaphragm pump is turned on after the air compressing air unit 12 is turned on. The ink passes through the pneumatic diaphragm pump, the filter 11 and the ink supply valve 15 slowly and is pumped into the ink path system 7 of the ink-jet printer. Meanwhile, the motor 9 drives the stirring paddle 10 to keep a slowly uniform stirring state all the time. The detection data displayed by the gravity sensor 17 can judge whether ink needs to be added. When ink needs to be replenished again, the feed valve 18 is opened, the discharge valve 19 is closed, the pneumatic diaphragm pump, the ink supply valve 15 and the return valve 16 are closed, and then ink is replenished.

The foregoing is a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, many modifications and decorations can be made without departing from the principle of the invention, and these modifications and decorations are also regarded as the protection scope of the present invention.

Claims (10)

1. A ceramic ink transfer device is characterized by comprising a supporting platform, a ceramic ink transfer cylinder, an ink feeding pipeline, an ink discharging pipeline, an ink pump, an ink supplying pipeline, an ink path system of an ink jet printer and a return pipeline, wherein the ceramic ink transfer cylinder is arranged on the supporting platform;

the ceramic ink rotary cylinder is arranged on the supporting platform, the ink feeding pipeline is connected with the ceramic ink rotary cylinder, the ceramic ink rotary cylinder is connected with one end of the ink discharging pipeline, the other end of the ink discharging pipeline is connected with the ink pump, the ink pump is connected with one end of the ink supplying pipeline, and the other end of the ink supplying pipeline is connected with the ink path system of the ink jet printer;

the ink pump is further connected with one end of the backflow pipeline, and the other end of the backflow pipeline is connected with the ceramic ink transfer cylinder.

2. The ceramic ink transfer device of claim 1, further comprising a motor and a paddle, wherein the paddle is mounted to the motor, and the motor is disposed on a top of the ceramic ink transfer cylinder such that the paddle is disposed on a bottom of the ceramic ink transfer cylinder.

3. The ceramic ink transfer device of claim 1, further comprising a filter, wherein the ink pump is connected to the filter, the filter is connected to one end of the ink supply pipe, and the other end of the ink supply pipe is connected to the ink path system of the inkjet printer;

the filter device is further connected with one end of the backflow pipeline, and the other end of the backflow pipeline is connected with the ceramic ink transfer cylinder.

4. The ceramic ink transfer device of claim 2, further comprising a compressed air device and a compressed air source conduit, wherein the ink pump is a pneumatic diaphragm pump, the compressed air device is connected to the compressed air source conduit, and the compressed air source conduit is connected to the pneumatic diaphragm pump.

5. The ceramic ink transfer device of claim 4, wherein a mounting valve is provided at a connection front end of the pneumatic diaphragm pump.

6. The ceramic ink transfer device of claim 4, wherein the motor is a pneumatic motor, the compressed air device is connected to the compressed air source pipeline, and the compressed air source pipeline is connected to the pneumatic motor.

7. The ceramic ink transfer device of claim 1, further comprising an ink supply valve and a return valve;

the ink supply pipeline is connected with the ink supply valve, the ink supply valve is connected with the ink path system of the ink-jet printer, the backflow pipeline is connected with the backflow valve, and the backflow valve is connected with the ceramic ink transfer cylinder.

8. The ceramic ink transfer device of claim 1, further comprising a gravity sensor, wherein the gravity sensor is mounted between the ceramic ink transfer cylinder and the support platform.

9. The ceramic ink transfer device of claim 1, further comprising a feed valve and a discharge valve;

the feeding valve is installed at the feeding hole of the ceramic ink rotary cylinder, the feeding hole is connected with the ink feeding pipeline through the feeding valve, the discharging valve is installed at the discharging hole of the ceramic ink rotary cylinder, and the discharging hole is connected with the ink discharging pipeline through the discharging valve port.

10. The ceramic ink transfer device of claim 1, wherein a vent hole is formed at a top end of the ceramic ink transfer cylinder, and a filter screen is wrapped around the vent hole.

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