CN111468029B - Water-based ink thickening device - Google Patents

Abstract

The invention relates to water-based ink, in particular to a water-based ink thickening device. The invention aims to provide a thickening device for water-based ink. A water-based ink thickening device comprises a fixed support, a control switch, a motor, a first driving wheel, a second driving wheel, an ink heavy reaction mechanism, a flow-changing recovery mechanism and a quantitative ink distributing mechanism; the left middle part of the front end of the fixed support is connected with the control switch through a bolt; the middle left part in the fixed support is connected with the motor through a bolt; the right part of the top end of the fixed support is provided with an ink heavy reaction mechanism; the right middle part in the fixed support is provided with a flow-changing recovery mechanism. The invention achieves the effects of preventing the ink from settling in a natural state, causing uneven concentration, recovering and remixing the water-based ink liquid which is easy to generate water ripples when the ink is used, and meeting the requirement of putting into production.

Description

Water-based ink thickening device

Technical Field

The invention relates to water-based ink, in particular to a water-based ink thickening device.

Background

The water-based ink uses water as a dissolving carrier, and has the obvious characteristics of environmental protection and safety: the printing method is safe, non-toxic, harmless, non-combustible, non-explosive and almost free of volatile organic gases, and mainly shows the effects of not polluting the environment, reducing residual toxicants and reducing consumption and cost.

To sum up, need research and develop an effect that reduces printing ink concentration at present to reached and prevented that printing ink from subsiding under natural state, lead to the concentration inhomogeneous, retrieve the aqueous ink liquid that produces the water ripple phenomenon easily when using printing ink, reconcile once more, reach the aqueous ink thickening device that can put into production's demand, overcome among the prior art aqueous ink and use shallow version to print, the concentration is not enough often the phenomenon of water ripple often, can not store for a long time, easily form the shortcoming of sediment.

Disclosure of Invention

The invention aims to overcome the defects that in the prior art, the water-based ink is printed by a shallow plate, the concentration is insufficient, the phenomenon of water ripples is frequent, the water ripples cannot be stored for a long time, and precipitates are easy to form, and the technical problem to be solved by the invention is to provide a water-based ink thickening device.

The invention is achieved by the following specific technical means:

a water-based ink thickening device comprises a fixed support, a control switch, a motor, a first driving wheel, a second driving wheel, an ink heavy reaction mechanism, a flow-changing recovery mechanism and a quantitative ink distributing mechanism; the left middle part of the front end of the fixed support is connected with the control switch through a bolt; the left side inside the fixed support is connected with a motor through a bolt; the right part of the top end of the fixed support is provided with an ink heavy reaction mechanism; the right side in the fixed support is provided with a flow-changing recovery mechanism, and the top end of the flow-changing recovery mechanism is connected with the ink re-reaction mechanism; the left part of the top end of the fixed support is provided with a quantitative ink distribution mechanism, and the bottom of the right end of the quantitative ink distribution mechanism is connected with the ink re-reaction mechanism; the middle part of the front end of the motor is inserted with the first transmission wheel, and the right end of the first transmission wheel is connected with the ink re-reaction mechanism through a belt; the middle part of the front end of the first driving wheel is spliced with the second driving wheel through a round rod, and the top end of the second driving wheel is connected with the quantitative ink distributing mechanism through a belt.

Further, the ink re-reaction mechanism comprises a third transmission wheel, a first bevel gear, a second bevel gear, a first fixing frame, a first polish rod, a first straight gear, a second polish rod, a second straight gear, a lifting claw, a rotating shaft seat, a stirrer, a re-reaction cabin, a first top cover, a discharge guide pipe, a guide net grid and a pressing stop connecting rod; the middle part of the front end of the third driving wheel is inserted with the first bevel gear; a second bevel gear is arranged at the top of the front end of the first bevel gear; the middle part of the rear end of the first bevel gear is rotationally connected with the first fixing frame through a round rod; the middle part of the top end of the second bevel gear is inserted with the first straight gear; the right part in the first fixing frame is in sliding connection with the first polish rod; the middle part of the left end of the first fixing frame is welded with the second polished rod; the left end of the first straight gear is meshed with the second straight gear; the bottom end of the second straight gear is provided with a lifting claw; the middle part of the inner surface of the second straight gear is sleeved with the stirrer; the bottom end of the lifting claw is rotatably connected with the rotating shaft seat; the bottom of the outer surface of the stirrer is rotationally connected with the heavy reaction cabin; a first top cover is arranged at the top end of the heavy reaction cabin; the middle part of the bottom end of the heavy reaction cabin is spliced with the discharge conduit; the middle bottom of the inner surface of the discharging conduit is rotationally connected with the material guiding grid; the top end of the material guide mesh grid is rotatably connected with a pressure stop connecting rod, the top end of the pressure stop connecting rod is hinged with the rotating shaft seat, and the pressure stop connecting rod is positioned at the front part of the second polished rod; the right end of the third transmission wheel is connected with the first transmission wheel through a belt; the bottom end of the third driving wheel is connected with the reflow collecting mechanism through a belt; the front end and the rear end of the first polished rod are both connected with the fixed bracket; the bottom end of the heavy reaction cabin is connected with the fixed bracket; the middle top of the front end of the re-reaction cabin is connected with the reflow collecting mechanism; the middle top of the right end of the heavy reaction cabin is connected with the quantitative ink distributing mechanism; the bottom end of the discharge conduit is connected with the reflow collecting mechanism.

Further, the reflow collecting mechanism comprises a fourth driving wheel, a third bevel gear, a fourth bevel gear, a third straight gear, an armature-shaped guide plate, a discharging tail pipe, a first reflux pipe, a pump machine and a second reflux pipe; the middle part of the left end of the fourth driving wheel is inserted with the third bevel gear; the rear part of the left end of the third bevel gear is meshed with the fourth bevel gear; the middle part of the rear end of the fourth bevel gear is inserted with the third straight gear; the left end of the third straight gear is meshed with the stomach-shaped guide plate; the left top of the front end of the stomach-shaped guide plate and the left top of the rear end of the stomach-shaped guide plate are both rotationally connected with the discharging tail pipe; the left end of the discharge tail pipe is connected with the first reflux pipe through a bolt; the middle part of the top end of the pump is connected with the second return pipe through a bolt; the top end of the fourth transmission wheel is connected with the third transmission wheel through a belt; the top end of the discharge tail pipe is connected with a discharge conduit; the left part of the outer surface of the first reflux pipe is connected with the fixed bracket; the middle part of the outer surface of the second return pipe is connected with the fixed bracket; the top of the right end of the second return pipe is connected with the heavy reaction cabin.

Further, the quantitative ink distributing mechanism comprises a fifth transmission wheel, a fourth straight gear, a long gear, a fifth straight gear, an electric push rod, a screw rod, a rotation limiting block, an ink adding conduit, a longitudinal shaft limiting frame, a sliding frame, a reversing and positioning rod, a fixing plate, an ink pouring funnel, a first poking valve, an ink storage tank, a second poking valve and a second top cover; the middle part of the right end of the fifth transmission wheel is spliced with the fourth straight gear; the front end of the fourth straight gear is provided with a long gear; a fifth straight gear is arranged at the bottom of the front end of the fourth straight gear, and the fifth straight gear is positioned at the right bottom of the rear end of the long gear; the right end of the long gear is spliced with the screw rod; the bottom end of the fifth straight gear is rotationally connected with the electric push rod through a fixed block; the left part of the outer surface of the screw rod is rotationally connected with a rotation limiting block; an ink adding guide pipe is arranged at the right part of the rear end of the screw rod; the bottom of the ink adding guide pipe is connected with the heavy reaction cabin; the right end of the screw rod is rotationally connected with the longitudinal axis limiting frame; the left part of the outer surface of the longitudinal axis limiting frame and the right part of the outer surface of the longitudinal axis limiting frame are in sliding connection with the sliding frame; the middle part in the sliding frame is in transmission connection with the reversing position adjusting rod through a round pin; the middle part of the top end of the reversing and positioning rod is inserted into the fixed plate; the inner rear part of the fixing plate is welded with the ink inverted duct; the right middle part of the bottom end of the ink pouring duct is welded with the first stirring valve; the top end of the ink pouring duct is provided with an ink storage tank; the right part of the bottom end of the ink storage tank is welded with a second shifting valve, and the second shifting valve is positioned at the top of the ink pouring duct; a second top cover is arranged at the top end of the ink storage tank; the bottom end of the fifth driving wheel is connected with the second driving wheel through a belt; the middle part of the front end of the fifth driving wheel is connected with the fixed bracket through a round rod; the front end of the rotation limiting block is connected with the heavy reaction cabin; the bottom end of the sliding frame is connected with the heavy reaction cabin through a mounting block; the bottom end of the ink storage tank is connected with the fixed bracket.

Furthermore, the second shifting valve comprises a rectangular sliding frame, a spring, a valve plate and a shifting block; the right end in the rectangular sliding frame is welded with the spring; the left part of the inner front end and the left part of the inner rear end of the rectangular sliding frame are in sliding connection with the valve plate, and the right end of the valve plate is connected with the spring; the left part of the front end of the valve plate is welded with the shifting block; the top end of the rectangular sliding frame is welded with the ink storage tank.

Furthermore, a hole groove is formed in the second straight gear.

Further, armature shape guide plate sets up to offset when armature shape guide plate left end bottom offsets with first return pipe, and armature shape guide plate blocks ejection of compact tail pipe circulation.

Further, first valve and the second of dialling are dialled the valve structure and are the same to the shifting block left end is provided with curved disappearance.

Compared with the prior art, the invention has the following beneficial effects:

in order to solve the problems that the prior art uses a shallow plate to print the water-based ink, the concentration of the water-based ink is insufficient, the water ripple phenomenon is often caused, the water-based ink cannot be stored for a long time, and precipitates are easily formed, an ink heavy reaction mechanism, a flow change recovery mechanism and a quantitative ink distribution mechanism are designed, the flow change recovery mechanism is linked through the ink heavy reaction mechanism, the flow change recovery mechanism is used for recovering the water-based ink liquid with the concentration which does not meet the requirements and is easy to generate the water ripple phenomenon when the ink is used, meanwhile, the quantitative ink distribution mechanism is used for quantitatively adding dry ink raw materials into the ink heavy reaction mechanism, the ink heavy reaction mechanism is used for blending again, so that the water-based ink reaches the usable consistency, then the water-based ink can be discharged for production, when the concentration of the ink is too high, the water infiltration effect is superior to the infiltration effect of solutes, and then the water is slowly and naturally infiltrated through the ink heavy reaction mechanism, therefore, the effects of preventing the ink from settling under the natural state, causing uneven concentration, recovering the water-based ink liquid which is easy to generate the phenomenon of water ripple when the ink is used, and blending again to meet the requirement of putting into production are achieved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic diagram of an ink re-reaction mechanism according to the present invention;

FIG. 3 is a schematic view of a material guiding grid structure according to the present invention;

FIG. 4 is a schematic diagram of the structure of the reflow recycling mechanism of the present invention;

FIG. 5 is a schematic structural diagram of a quantitative ink distributing mechanism according to the present invention;

FIG. 6 is a schematic view of a combined structure of an ink fountain and a first valve;

FIG. 7 is a schematic view of an ink tank and a second dial valve according to the present invention;

fig. 8 is a schematic structural diagram of a second dial valve of the present invention.

The labels in the figures are: 1-a fixed bracket, 2-a control switch, 3-a motor, 4-a first driving wheel, 5-a second driving wheel, 6-an ink heavy reaction mechanism, 7-a diversion recovery mechanism, 8-a quantitative ink distribution mechanism, 601-a third driving wheel, 602-a first bevel gear, 603-a second bevel gear, 604-a first fixed frame, 605-a first polished rod, 606-a first straight gear, 607-a second polished rod, 608-a second straight gear, 609-a lifting claw, 6010-a rotating shaft seat, 6011-a stirrer, 6012-a heavy reaction chamber, 6013-a first top cover, 6014-a discharge conduit, 6015-a guide grid, 6016-a pressure stop connecting rod, 701-a fourth driving wheel, 702-a third bevel gear, 703-a fourth bevel gear, 704-a third spur gear, 705-an armature-shaped guide plate, 706-a discharge tail pipe, 707-a first return pipe, 708-a pump, 709-a second return pipe, 801-a fifth transmission wheel, 802-a fourth spur gear, 803-a long gear, 804-a fifth spur gear, 805-an electric push rod, 806-a screw rod, 807-a rotation limiting block, 808-an ink adding pipe, 809-a longitudinal axis limiting frame, 8010-a sliding frame, 8011-a reversing positioning rod, 8012-a fixing plate, 8013-an ink pouring hopper, 8014-a first poking valve, 8015-an ink storage tank, 8016-a second poking valve, 8017-a second top cover, 801601-a rectangular sliding frame, 801602-a spring, 801603-a valve plate and 801604-a poking block.

Detailed Description

The invention is further described below with reference to the figures and examples.

Examples

An aqueous ink thickening device is shown in figures 1-8 and comprises a fixed support 1, a control switch 2, a motor 3, a first driving wheel 4, a second driving wheel 5, an ink re-reaction mechanism 6, a flow-back collecting mechanism 7 and a quantitative ink distributing mechanism 8; the left middle part of the front end of the fixed support 1 is connected with the control switch 2 through a bolt; the middle left part in the fixed support 1 is connected with the motor 3 through a bolt; the right part of the top end of the fixed support 1 is provided with an ink heavy reaction mechanism 6; a flow-changing recovery mechanism 7 is arranged in the middle right part in the fixed support 1, and the top end of the flow-changing recovery mechanism 7 is connected with the ink re-reaction mechanism 6; the left part of the top end of the fixed support 1 is provided with a quantitative ink distribution mechanism 8, and the bottom of the right end of the quantitative ink distribution mechanism 8 is connected with the ink heavy reaction mechanism 6; the middle part of the front end of the motor 3 is inserted with the first driving wheel 4, and the right end of the first driving wheel 4 is connected with the ink heavy reaction mechanism 6 through a belt; the middle part of the front end of the first driving wheel 4 is spliced with the second driving wheel 5 through a round rod, and the top end of the second driving wheel 5 is connected with the quantitative ink distributing mechanism 8 through a belt.

The ink re-reaction mechanism 6 comprises a third driving wheel 601, a first bevel gear 602, a second bevel gear 603, a first fixing frame 604, a first polish rod 605, a first straight gear 606, a second polish rod 607, a second straight gear 608, a lifting claw 609, a rotating shaft seat 6010, a stirrer 6011, a re-reaction cabin 6012, a first top cover 6013, a discharging conduit 6014, a guide net grid 6015 and a pressure stopping connecting rod 6016; the middle part of the front end of the third driving wheel 601 is inserted into the first bevel gear 602; a second bevel gear 603 is arranged at the top of the front end of the first bevel gear 602; the middle part of the rear end of the first bevel gear 602 is rotationally connected with a first fixing frame 604 through a round rod; the middle part of the top end of the second bevel gear 603 is inserted with the first straight gear 606; the right part in the first fixing frame 604 is connected with a first polish rod 605 in a sliding way; the middle part of the left end of the first fixing frame 604 is welded with a second polish rod 607; the left end of the first spur gear 606 is meshed with a second spur gear 608; the bottom end of the second straight gear 608 is provided with a lifting claw 609; the middle part of the inner surface of the second straight gear 608 is sleeved with the stirrer 6011; the bottom end of the lifting claw 609 is rotatably connected with the rotating shaft seat 6010; the bottom of the outer surface of the stirrer 6011 is rotatably connected with the heavy reaction cabin 6012; a first top cover 6013 is arranged at the top end of the heavy reaction cabin 6012; the middle part of the bottom end of the heavy reaction cabin 6012 is spliced with a discharge conduit 6014; the middle bottom of the inner surface of the discharge conduit 6014 is rotatably connected with a guide grid 6015; the top end of the guide net grid 6015 is rotatably connected with a press-stopping connecting rod 6016, the top end of the press-stopping connecting rod 6016 is hinged with the rotating shaft seat 6010, and the press-stopping connecting rod 6016 is located at the front part of the second polish rod 607; the right end of the third transmission wheel 601 is connected with the first transmission wheel 4 through a belt; the bottom end of the third driving wheel 601 is connected with the reflow collecting mechanism 7 through a belt; the front end and the rear end of the first polish rod 605 are both connected with the fixed bracket 1; the bottom end of the heavy reaction cabin 6012 is connected with the fixed support 1; the middle top of the front end of the heavy reaction cabin 6012 is connected with a reflow collecting mechanism 7; the middle top of the right end of the heavy reaction cabin 6012 is connected with a quantitative ink distributing mechanism 8; the bottom end of the discharge conduit 6014 is connected to the reflux recovery mechanism 7.

The diversion recovery mechanism 7 comprises a fourth driving wheel 701, a third bevel gear 702, a fourth bevel gear 703, a third spur gear 704, an armature-shaped guide plate 705, a discharge tail pipe 706, a first return pipe 707, a pump machine 708 and a second return pipe 709; the middle part of the left end of the fourth transmission wheel 701 is spliced with a third bevel gear 702; the rear part of the left end of the third bevel gear 702 is meshed with a fourth bevel gear 703; the middle part of the rear end of the fourth bevel gear 703 is spliced with a third straight gear 704; the left end of the third spur gear 704 engages the armature shaped deflector 705; the left top of the front end and the left top of the back end of the armature-shaped guide plate 705 are both rotationally connected with a discharge tail pipe 706; the left end of the discharge tail pipe 706 is connected with a first return pipe 707 through a bolt; the middle part of the top end of the pump 708 is connected with a second return pipe 709 through a bolt; the top end of the fourth transmission wheel 701 is connected with the third transmission wheel 601 through a belt; the top end of the discharge tail pipe 706 is connected with a discharge conduit 6014; the left part of the outer surface of the first return pipe 707 is connected with the fixed bracket 1; the middle part of the outer surface of the second return pipe 709 is connected with the fixed bracket 1; the top of the right end of the second return pipe 709 is connected with the heavy reaction cabin 6012.

The quantitative ink distributing mechanism 8 comprises a fifth driving wheel 801, a fourth spur gear 802, a long gear 803, a fifth spur gear 804, an electric push rod 805, a screw rod 806, a rotation limiting block 807, an ink adding conduit 808, a longitudinal axis limiting frame 809, a sliding frame 8010, a reversing position adjusting rod 8011, a fixing plate 8012, an ink pouring funnel 8013, a first poking valve 8014, an ink storage tank 8015, a second poking valve 8016 and a second top cover 8017; the middle part of the right end of the fifth transmission wheel 801 is spliced with a fourth straight gear 802; the front end of the fourth spur gear 802 is provided with a long gear 803; a fifth spur gear 804 is arranged at the bottom of the front end of the fourth spur gear 802, and the fifth spur gear 804 is positioned at the right bottom of the rear end of the long gear 803; the right end of the long gear 803 is inserted into the screw rod 806; the bottom end of the fifth straight gear 804 is rotatably connected with an electric push rod 805 through a fixed block; the left part of the outer surface of the screw rod 806 is rotationally connected with a rotation limiting block 807; an ink adding conduit 808 is arranged at the right part of the rear end of the screw rod 806; the bottom of the ink adding conduit 808 is connected with the heavy reaction cabin 6012; the right end of the screw rod 806 is rotatably connected with a longitudinal axis limit frame 809; the left part and the right part of the outer surface of the longitudinal axis limiting frame 809 are in sliding connection with the sliding frame 8010; the middle part in the sliding frame 8010 is in transmission connection with the reversing positioning rod 8011 through a round pin; the middle part of the top end of the reversing position adjusting rod 8011 is spliced with the fixed plate 8012; the inner rear part of the fixing plate 8012 is welded with the inverted ink fountain 8013; the right middle part of the bottom end of the ink pouring duct 8013 is welded with the first toggle valve 8014; an ink storage tank 8015 is arranged at the top end of the ink pouring duct 8013; the right part of the bottom end of the ink storage tank 8015 is welded with the second poking valve 8016, and the second poking valve 8016 is positioned at the top of the ink pouring duct 8013; a second top cover 8017 is arranged at the top end of the ink storage tank 8015; the bottom end of the fifth driving wheel 801 is connected with the second driving wheel 5 through a belt; the middle part of the front end of the fifth transmission wheel 801 is connected with the fixed bracket 1 through a round rod; the front end of the rotation limiting block 807 is connected with the heavy reaction cabin 6012; the bottom end of the sliding frame 8010 is connected with the heavy reaction cabin 6012 through a mounting block; the bottom end of the ink storage tank 8015 is connected with the fixed bracket 1.

The second toggle valve 8016 comprises a rectangular slide frame 801601, a spring 801602, a valve plate 801603 and a toggle block 801604; the right end in the rectangular sliding frame 801601 is welded with a spring 801602; the left part of the inner front end and the left part of the inner rear end of the rectangular sliding frame 801601 are both in sliding connection with the valve plate 801603, and the right end of the valve plate 801603 is connected with the spring 801602; the left part of the front end of the valve plate 801603 is welded with the shifting block 801604; the top of the rectangular slide frame 801601 is welded to the ink reservoir 8015.

The second spur gear 608 has a hole groove formed therein.

The armature-shaped deflector 705 is positioned such that when the bottom of the left end of the armature-shaped deflector 705 abuts the first return conduit 707, the armature-shaped deflector 705 blocks the flow through the tailpipe 706.

The first toggle valve 8014 and the second toggle valve 8016 are identical in structure, and the left end of the toggle block 801604 is provided with an arc-shaped missing part.

The working principle is as follows: when the water-based ink thickening device is used, the device is firstly placed on a horizontal working surface of a processing workshop, then the control switch 2 is used for starting each mechanism to operate, then the initially well-blended ink is stirred by the ink re-reaction mechanism 6, the ink is prevented from settling under a natural state and causing uneven concentration, when the concentration is too low, the ink re-reaction mechanism 6 is linked and changed to flow back to the collecting mechanism 7 mechanism, the flow-changing and recovering mechanism 7 is used for recovering the water-based ink liquid which does not meet the requirement of the concentration and is easy to generate water ripples when the ink is used, meanwhile, the quantitative ink distributing mechanism 8 is used for quantitatively adding dry ink raw materials into the ink re-reaction mechanism 6, the ink re-reaction mechanism 6 is used for re-blending, so that the water-based ink reaches the usable consistency, then the water-based ink can be discharged for production, when the concentration of the ink is too high, the effect of water to the infiltration is superior to that of solute, and the slow natural infiltration is carried out through the ink heavy reaction mechanism 6, so that the effect of reducing the concentration of the ink is achieved, the effect of preventing the ink from settling under the natural state and causing the uneven concentration is achieved, the water-based ink liquid which is easy to generate the phenomenon of water ripple when the ink is used is recovered and is blended again, and the requirement of putting into production is met.

The device comprises a third driving wheel 601, a first bevel gear 602, a second bevel gear 603, a first fixing frame 604, a first polished rod 605, a first straight gear 606, a second polished rod 607, a second straight gear 608, a lifting claw 609, a rotating shaft seat 6010, a stirrer 6011, a heavy reaction cabin 6012, a first top cover 6013, a discharging guide pipe 6014, a material guide net 6015 and a pressure stopping connecting rod 6016; the middle part of the front end of the third driving wheel 601 is inserted with the first bevel gear 602; the top of the front end of the first bevel gear 602 is meshed with a second bevel gear 603; the middle part of the rear end of the first bevel gear 602 is rotationally connected with a first fixing frame 604 through a round rod; the middle part of the top end of the second bevel gear 603 is inserted with the first straight gear 606; the right part in the first fixed frame 604 is connected with a first polish rod 605 in a sliding way; the middle part of the left end of the first fixing frame 604 is welded with the second polish rod 607; the left end of the first straight gear 606 is meshed with a second straight gear 608; the bottom end of the second straight gear 608 is provided with a lifting claw 609; the middle part of the inner surface of the second straight gear 608 is sleeved with a stirrer 6011; the bottom end of the lifting claw 609 is rotatably connected with the rotating shaft seat 6010; the bottom of the outer surface of the stirrer 6011 is rotatably connected with the heavy reaction cabin 6012; a first top cover 6013 is arranged at the top end of the heavy reaction cabin 6012; the middle part of the bottom end of the heavy reaction cabin 6012 is spliced with a discharge conduit 6014; the middle bottom of the inner surface of the discharge conduit 6014 is rotatably connected with a guide grid 6015; the top end of the guide net grid 6015 is rotatably connected with a press-stopping connecting rod 6016, the top end of the press-stopping connecting rod 6016 is hinged with the rotating shaft seat 6010, and the press-stopping connecting rod 6016 is located at the front part of the second polish rod 607; the right end of the third transmission wheel 601 is connected with the first transmission wheel 4 through a belt; the bottom end of the third driving wheel 601 is connected with the reflow collecting mechanism 7 through a belt; the front end and the rear end of the first polish rod 605 are both connected with the fixed bracket 1; the bottom end of the heavy reaction cabin 6012 is connected with the fixed support 1; the middle top of the front end of the heavy reaction cabin 6012 is connected with a reflow collecting mechanism 7; the middle top of the right end of the heavy reaction cabin 6012 is connected with a quantitative ink distributing mechanism 8; the bottom end of the discharge conduit 6014 is connected to a reflow collecting mechanism 7.

When the ink re-reaction mechanism 6 is used, the rotation of the third driving wheel 601 drives the first bevel gear 602 to rotate, when the concentration is lower, the flow of the passing guide grid 6015 is increased, then the guide grid 6015 is pressed downwards, then the first fixing frame 604 slides downwards by utilizing the downward inclination trend of the front end of the first polish rod 605, the first bevel gear 602 is meshed with the second bevel gear 603, the rotation of the first bevel gear 602 is used to drive the second bevel gear 603 to rotate, the first straight gear 606 is driven to rotate, then the second straight gear 608 is meshed to rotate, simultaneously the pressing rotation of the guide grid 6015 pushes the pressing stop connecting rod 6016 to ascend, then the lifting claw 609 is driven to ascend, the second straight gear 608 is clamped with the stirrer 6011, simultaneously the rotation relationship between the lifting claw 609 and the rotating shaft seat 6010 is utilized, the rotation of the second straight gear 608 is rotated along with the rotation of the stirrer 6011, the ink liquid in the heavy reaction cabin 6012 is driven to be tempered, meanwhile, the ink in the heavy reaction cabin 6012 is prevented from standing and naturally precipitating, under the condition of high concentration, the flow of the passing guide net grid 6015 is reduced, the guide net grid 6015 bears insufficient stress and cannot be pressed down, then the flow is limited through the guide net grid 6015, meanwhile, the infiltration speed of water is higher than the infiltration speed of an ink solute, and therefore the discharging concentration of the water-based ink is increased, the effect of tempering different concentrations of the water-based ink is achieved, and the phenomenon of water ripples cannot occur in the using process of the water-based ink.

Comprises a fourth driving wheel 701, a third bevel gear 702, a fourth bevel gear 703, a third spur gear 704, an armature-shaped guide plate 705, a discharge tail pipe 706, a first return pipe 707, a pump 708 and a second return pipe 709; the middle part of the left end of the fourth transmission wheel 701 is spliced with a third bevel gear 702; the rear part of the left end of the third bevel gear 702 is meshed with a fourth bevel gear 703; the middle part of the rear end of the fourth bevel gear 703 is spliced with a third straight gear 704; the left end of the third spur gear 704 engages the armature shaped deflector 705; the left top of the front end and the left top of the back end of the armature-shaped guide plate 705 are both rotationally connected with a discharge tail pipe 706; the left end of the discharge tail pipe 706 is connected with a first return pipe 707 through a bolt; the middle part of the top end of the pump 708 is connected with a second return pipe 709 through a bolt; the top end of the fourth transmission wheel 701 is connected with the third transmission wheel 601 through a belt; the top end of the discharge tail pipe 706 is connected with a discharge conduit 6014; the left part of the outer surface of the first return pipe 707 is connected with the fixed bracket 1; the middle part of the outer surface of the second return pipe 709 is connected with the fixed bracket 1; the top of the right end of the second return pipe 709 is connected with the heavy reaction cabin 6012.

When the diversion recovery mechanism 7 is used, the third bevel gear 702 is driven to rotate by the rotation of the fourth driving wheel 701, then the fourth bevel gear 703 is driven to rotate by meshing, then the third spur gear 704 rotates, the meshing transmission armature-shaped guide plate 705 rotates in the discharging tail pipe 706, the flow of the discharging tail pipe 706 is stopped, then the aqueous ink solution in the discharging tail pipe 706 is led into the first return pipe 707, and then the aqueous ink is led into the ink heavy reaction mechanism 6 by the pump 708 for thickening, so that the effects of recovering the aqueous ink with insufficient concentration and re-thickening are achieved.

The ink filling device comprises a fifth driving wheel 801, a fourth spur gear 802, a long gear 803, a fifth spur gear 804, an electric push rod 805, a screw rod 806, a rotation limiting block 807, an ink filling conduit 808, a longitudinal axis limiting frame 809, a sliding frame 8010, a reversing position adjusting rod 8011, a fixing plate 8012, an ink pouring funnel 8013, a first toggle valve 8014, an ink storage tank 8015, a second toggle valve 8016 and a second top cover 8017; the middle part of the right end of the fifth transmission wheel 801 is spliced with a fourth straight gear 802; the front end of the fourth spur gear 802 is provided with a long gear 803; a fifth spur gear 804 is arranged at the bottom of the front end of the fourth spur gear 802, and the fifth spur gear 804 is positioned at the right bottom of the rear end of the long gear 803; the right end of the long gear 803 is inserted into the screw rod 806; the bottom end of the fifth straight gear 804 is rotatably connected with an electric push rod 805 through a fixed block; the left part of the outer surface of the screw rod 806 is rotationally connected with a rotation limiting block 807; an ink adding conduit 808 is arranged at the right part of the rear end of the screw rod 806; the right end of the screw rod 806 is rotatably connected with a longitudinal axis limit frame 809; the left part and the right part of the outer surface of the longitudinal axis limiting frame 809 are connected with the sliding frame 8010 in a sliding way; the middle part in the sliding frame 8010 is in transmission connection with the reversing position adjusting rod 8011 through a round pin; the middle part of the top end of the reversing position adjusting rod 8011 is spliced with the fixed plate 8012; the inner rear part of the fixing plate 8012 is welded with the inverted ink fountain 8013; the right middle part of the bottom end of the ink pouring duct 8013 is welded with the first toggle valve 8014; an ink storage tank 8015 is arranged at the top end of the ink pouring duct 8013; the right part of the bottom end of the ink storage tank 8015 is welded with the second poking valve 8016, and the second poking valve 8016 is positioned at the top of the ink pouring duct 8013; a second top cover 8017 is arranged at the top end of the ink storage tank 8015; the bottom end of the fifth driving wheel 801 is connected with the second driving wheel 5 through a belt; the middle part of the front end of the fifth transmission wheel 801 is connected with the fixed bracket 1 through a round rod; the front end of the rotation limiting block 807 is connected with the heavy reaction cabin 6012; the bottom end of the sliding frame 8010 is connected with the heavy reaction cabin 6012 through a mounting block; the bottom end of the ink storage tank 8015 is connected with the fixed bracket 1.

When the ink adding device is used, the fourth spur gear 802 is driven to rotate through the rotation of the fifth driving wheel 801, when the ink adding raw material is added for thickening, the electric push rod 805 is pushed upwards, then the fifth spur gear 804 is simultaneously meshed with the fourth spur gear 802 and the long gear 803, then the fifth spur gear 804 is meshed to rotate through the rotation of the fourth spur gear 802, then the long gear 803 is driven to rotate through meshing, the screw rod 806 moves rightwards while rotating due to the fact that the rotation limiting block 807 is meshed with the screw rod 806, then the longitudinal shaft limiting frame 809 moves rightwards, the front end of the reversing position adjusting rod 8011 is pushed rightwards, then the reversing position adjusting rod 8011 rotates for a right angle, meanwhile, the fixing plate 8012 is driven to rotate for a right angle, the ink pouring funnel 8013 is positioned at the top of the ink adding conduit 808, then the first poking valve 8014 is pushed to open to transfer the ink raw material in the ink pouring funnel 8013 into the ink adding conduit 808, after the fixed plate 8012 rotates reversely, the ink pouring duct 8013 is reset, the first shifting valve 8014 is closed, the second shifting valve 8016 is opened, and quantitative ink raw materials are received from the ink storage tank 8015, so that the effect of quantitatively adding the ink raw materials is achieved, and the situation that the viscosity of the water-based ink solution is increased suddenly due to excessive single-time adding of the raw materials and the water-based ink solution cannot be put into production directly is avoided.

The second toggle valve 8016 comprises a rectangular slide frame 801601, a spring 801602, a valve plate 801603 and a toggle block 801604; the right end in the rectangular sliding frame 801601 is welded with a spring 801602; the left part of the inner front end and the left part of the inner rear end of the rectangular sliding frame 801601 are both in sliding connection with the valve plate 801603, and the right end of the valve plate 801603 is connected with the spring 801602; the left part of the front end of the valve plate 801603 is welded with the shifting block 801604; the top of the rectangular slide frame 801601 is welded to the ink reservoir 8015.

When the ink pouring duct 8013 contacts the shifting block 801604, the shifting block 801604 is pushed rightwards, the spring 801602 is compressed, then the valve is opened to contain ink raw materials, and when the ink pouring duct 8013 leaves the shifting block 801604, the valve plate 801603 is pushed leftwards through the spring 801602, the raw material outlet is closed, and the effect of automatically opening and closing discharging without energy is achieved.

A hole groove is formed in the second straight gear 608, so that the second straight gear 608 and the lifting claw 609 are clamped, and the stirrer 6011 is linked to rotate.

The armature-shaped deflector 705 is arranged so that when the bottom of the left end of the armature-shaped deflector 705 abuts against the first return pipe 707, the armature-shaped deflector 705 blocks the flow of the discharging tail pipe 706, and the flowing direction of the aqueous oil is changed by the armature-shaped deflector 705, thereby achieving the operation effect.

The first toggle valve 8014 and the second toggle valve 8016 are identical in structure, and the left end of the toggle block 801604 is provided with an arc-shaped deletion, so that the toggle block 801604 is attached to the ink pouring duct 8013, and slippage is prevented in the movement process.

Although the present disclosure has been described in detail with reference to the exemplary embodiments, the present disclosure is not limited thereto, and it will be apparent to those skilled in the art that various modifications and changes can be made thereto without departing from the scope of the present disclosure.

Claims (5)

1. A water-based ink thickening device comprises a fixed support (1), a control switch (2), a motor (3), a first transmission wheel (4) and a second transmission wheel (5), and is characterized by further comprising an ink heavy reaction mechanism (6), a flow changing and recovering mechanism (7) and a quantitative ink distributing mechanism (8); the left middle part of the front end of the fixed support (1) is connected with the control switch (2) through a bolt; the left side inside the fixed support (1) is connected with the motor (3) through a bolt; the right part of the top end of the fixed support (1) is provided with an ink heavy reaction mechanism (6); a flow-changing recovery mechanism (7) is arranged on the right side in the fixed support (1), and the top end of the flow-changing recovery mechanism (7) is connected with the ink re-reaction mechanism (6); the left part of the top end of the fixed support (1) is provided with a quantitative ink distribution mechanism (8), and the bottom of the right end of the quantitative ink distribution mechanism (8) is connected with the ink re-reaction mechanism (6); the middle part of the front end of the motor (3) is inserted into the first transmission wheel (4), and the right end of the first transmission wheel (4) is connected with the ink heavy reaction mechanism (6) through a belt; the middle part of the front end of the first driving wheel (4) is spliced with a second driving wheel (5) through a round rod, and the top end of the second driving wheel (5) is connected with a quantitative ink distributing mechanism (8) through a belt;

the ink re-reaction mechanism (6) comprises a third transmission wheel (601), a first bevel gear (602), a second bevel gear (603), a first fixing frame (604), a first polished rod (605), a first straight gear (606), a second polished rod (607), a second straight gear (608), a lifting claw (609), a rotating shaft seat (6010), a stirrer (6011), a re-reaction cabin (6012), a first top cover (6013), a discharging guide pipe (6014), a guide net grid (6015) and a pressure stop connecting rod (6016); the middle part of the front end of the third driving wheel (601) is inserted with the first bevel gear (602); a second bevel gear (603) is arranged at the top of the front end of the first bevel gear (602); when the concentration is low, the flow of the passing guide net grating (6015) is increased, then the guide net grating (6015) is pressed downwards, then the first fixing frame (604) slides downwards by utilizing the downward inclination trend of the front end of the first polished rod (605), the first bevel gear (602) is meshed with the second bevel gear (603), the first bevel gear (602) drives the second bevel gear (603) to rotate, so that the ink liquid in the heavy reaction cabin (6012) is blended in a matching manner, meanwhile, the ink in the heavy reaction cabin (6012) is prevented from standing and naturally precipitating, when the concentration is high, the flow of the passing guide net grating (6015) is reduced, the guide net grating (6015) bears insufficient stress and cannot be pressed downwards, and the first bevel gear (602) is disengaged from the second bevel gear (603); the middle part of the rear end of the first bevel gear (602) is rotationally connected with the first fixing frame (604) through a round rod; the middle part of the top end of the second bevel gear (603) is spliced with the first straight gear (606); the right part in the first fixing frame (604) is connected with a first polish rod (605) in a sliding way; the middle part of the left end of the first fixing frame (604) is welded with a second polished rod (607); the left end of the first straight gear (606) is meshed with the second straight gear (608); a lifting claw (609) is arranged at the bottom end of the second straight gear (608); the middle part of the inner surface of the second straight gear (608) is sleeved with the stirrer (6011); the bottom end of the lifting claw (609) is rotatably connected with a rotating shaft seat (6010); the bottom of the outer surface of the stirrer (6011) is rotatably connected with a heavy reaction cabin (6012); a first top cover (6013) is arranged at the top end of the heavy reaction cabin (6012); the middle part of the bottom end of the heavy reaction cabin (6012) is spliced with a discharge conduit (6014); the middle bottom of the inner surface of the discharge conduit (6014) is rotatably connected with a guide grid (6015); the top end of the material guide grid (6015) is rotatably connected with a press stopping connecting rod (6016), the top end of the press stopping connecting rod (6016) is hinged with a rotating shaft seat (6010), and the press stopping connecting rod (6016) is positioned at the front part of the second polished rod (607); the right end of the third transmission wheel (601) is connected with the first transmission wheel (4) through a belt; the bottom end of the third driving wheel (601) is connected with the flow-changing recovery mechanism (7) through a belt; the front end and the rear end of the first polish rod (605) are both connected with the fixed bracket (1); the bottom end of the heavy reaction cabin (6012) is connected with the fixed support (1); the middle top of the front end of the heavy reaction cabin (6012) is connected with a flow-changing recovery mechanism (7); the middle top of the right end of the heavy reaction cabin (6012) is connected with a quantitative ink distributing mechanism (8); the bottom end of the discharge conduit (6014) is connected with a flow-changing recovery mechanism (7);

the diversion recovery mechanism (7) comprises a fourth driving wheel (701), a third bevel gear (702), a fourth bevel gear (703), a third spur gear (704), a diversion plate (705), a discharge tail pipe (706), a first return pipe (707), a pump (708) and a second return pipe (709); the middle part of the left end of the fourth transmission wheel (701) is inserted with the third bevel gear (702); the rear part of the left end of the third bevel gear (702) is meshed with the fourth bevel gear (703); the middle part of the rear end of the fourth bevel gear (703) is spliced with the third straight gear (704); the left end of the third spur gear (704) engages the armature shaped deflector (705); the left top of the front end and the left top of the rear end of the armature-shaped guide plate (705) are both rotationally connected with a discharge tail pipe (706); the left end of the discharge tail pipe (706) is connected with a first return pipe (707) through a bolt; the middle part of the top end of the pump (708) is connected with a second return pipe (709) through a bolt; the top end of the fourth transmission wheel (701) is connected with the third transmission wheel (601) through a belt; the top end of the discharge tail pipe (706) is connected with a discharge conduit (6014); the left part of the outer surface of the first return pipe (707) is connected with the fixed bracket (1); the middle part of the outer surface of the second return pipe (709) is connected with the fixed bracket (1); the top of the right end of the second return pipe (709) is connected with a heavy reaction cabin (6012);

the quantitative ink distributing mechanism (8) comprises a fifth driving wheel (801), a fourth straight gear (802), a long gear (803), a fifth straight gear (804), an electric push rod (805), a screw rod (806), a rotation limiting block (807), an ink adding conduit (808), a longitudinal axis limiting frame (809), a sliding frame (8010), a reversing and positioning rod (8011), a fixing plate (8012), an ink pouring hopper (8013), a first toggle valve (8014), an ink storage tank (8015), a second toggle valve (8016) and a second top cover (8017); the middle part of the right end of the fifth driving wheel (801) is spliced with the fourth straight gear (802); a long gear (803) is arranged at the front end of the fourth straight gear (802); a fifth straight gear (804) is arranged at the bottom of the front end of the fourth straight gear (802), and the fifth straight gear (804) is positioned at the right bottom of the rear end of the long gear (803); the right end of the long gear (803) is inserted into the screw rod (806); the bottom end of the fifth straight gear (804) is rotatably connected with the electric push rod (805) through a fixed block; the left part of the outer surface of the screw rod (806) is rotationally connected with a rotation limiting block (807); an ink adding conduit (808) is arranged at the right part of the rear end of the screw rod (806); the bottom of the ink adding conduit (808) is connected with a heavy reaction cabin (6012); the right end of the screw rod (806) is rotationally connected with a longitudinal axis limit frame (809); the left part and the right part of the outer surface of the longitudinal axis limiting frame (809) are both connected with the sliding frame (8010) in a sliding way; the middle part in the sliding frame (8010) is in transmission connection with the reversing position adjusting rod (8011) through a round pin; the middle part of the top end of the reversing position adjusting rod (8011) is spliced with the fixed plate (8012); the inner rear part of the fixing plate (8012) is welded with the inverted ink fountain (8013); the right middle part of the bottom end of the ink pouring duct (8013) is welded with the first poking valve (8014); an ink storage tank (8015) is arranged at the top end of the ink pouring duct (8013); the right part of the bottom end of the ink storage tank (8015) is welded with a second poking valve (8016), and the second poking valve (8016) is positioned at the top of the ink pouring duct (8013); a second top cover (8017) is arranged at the top end of the ink storage tank (8015); the bottom end of the fifth driving wheel (801) is connected with the second driving wheel (5) through a belt; the middle part of the front end of the fifth transmission wheel (801) is connected with the fixed bracket (1) through a round rod; the front end of the rotation limiting block (807) is connected with a heavy reaction cabin (6012); the bottom end of the sliding frame (8010) is connected with a heavy reaction cabin (6012) through a mounting block; the bottom end of the ink storage tank (8015) is connected with the fixed bracket (1).

2. The aqueous ink thickening apparatus of claim 1, wherein the second toggle valve (8016) comprises a rectangular slide frame (801601), a spring (801602), a valve plate (801603) and a toggle block (801604); the right end in the rectangular sliding frame (801601) is welded with the spring (801602); the left part of the inner front end and the left part of the inner rear end of the rectangular sliding frame (801601) are in sliding connection with the valve plate (801603), and the right end of the valve plate (801603) is connected with the spring (801602); the left part of the front end of the valve plate (801603) is welded with the shifting block (801604); the top end of the rectangular sliding frame (801601) is welded with the ink storage tank (8015).

3. The aqueous ink thickening apparatus of claim 2, wherein the second spur gear (608) is internally provided with a bore and a groove.

4. The aqueous ink thickening apparatus of claim 3, wherein the flap (705) is configured such that when the bottom of the left end of the flap (705) abuts the first return pipe (707), the flap (705) blocks the flow through the outlet pipe (706).

5. The aqueous ink thickening apparatus of claim 4, wherein the first toggle valve (8014) and the second toggle valve (8016) are identical in structure, and the left end of the toggle block (801604) is provided with an arc-shaped absence.

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