CN216634832U - Air-washing high-pressure slip casting system - Google Patents

Abstract

The utility model discloses a gas-washing high-pressure grouting forming system which comprises a mold, a low-speed slurry stirring barrel, a high-pressure grouting system, a low-pressure slurry supply system and a hydraulic locking system, wherein the high-pressure grouting system comprises a hydraulic station, an oil-liquid medium pressure converter, a liquid medium-slurry pressure converter and a hydraulic energy accumulator, the hydraulic station is connected with the oil-liquid medium pressure converter through an electromagnetic valve, the hydraulic station is connected with the hydraulic energy accumulator, the oil-liquid medium pressure converter is connected with a liquid medium inlet of the liquid medium-slurry pressure converter, a slurry outlet of the liquid medium-slurry pressure converter is connected with the mold, and the hydraulic locking system is also connected with the high-pressure grouting system. The utility model has the advantages of high working efficiency, low labor intensity, low rejection rate and high product consistency.

Description

Air-washing high-pressure slip casting system

Technical Field

The utility model relates to the technical field of ceramic forming, in particular to a gas-washing high-pressure slip casting system.

Background

In the practical ceramic production activity, the models need to be carried and placed manually in the existing ceramic disc product production line, the weight of a single model is about 30kg on average, the operation intensity of workers is high, the working efficiency is low, and the working environment is relatively severe. In the production process, a worker needs to move the model 3 times (the model is placed on the grouting table, the model is taken down from the grouting table after grouting forming and placed on the operating table, the model is opened and placed on the grouting table again), the model is repeatedly moved, and the labor intensity is extremely high. Meanwhile, in the existing low-pressure grouting, the product forming time needs about 0.5 hour to complete a production cycle, workers need to time by themselves, the blank forming time can also change along with the change of the dryness and humidity of the model, the workers need to judge the forming time according to experience, certain requirements are required on the technical level of the workers, and the standardized production is not facilitated. And workers occasionally make a judgment error, open the mold early, the blank is not molded, and some of the blank is molded by demolding at that time, but the molding is not completed inside, the blank is seriously deformed, and a problem is found after firing, so that more loss is caused. The mold is opened late, the production efficiency is influenced, the blank begins to shrink after being formed in the mold, and the blank directly cracks in the mold, so that the yield is low. Even if the mold opening time is reasonably controlled, the water content of the green body is higher when the low-pressure grouting product is demolded, and the green body is still in a soft state without being shaped. The workman need utilize the layer board, takes out the product from the model, and this operation needs high proficiency, is unfavorable for the popularization of production, enlarges production.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Aiming at the defects of the prior art, the utility model provides the air-washing high-pressure slip casting system which is high in working efficiency, low in labor intensity, low in rejection rate and high in product consistency.

(II) technical scheme

In order to achieve the purpose, the utility model is realized by the following technical scheme: the utility model provides a gas wash high pressure slip casting system, includes the mould, its characterized in that: the high-pressure grouting system comprises a hydraulic station, an oil-liquid medium pressure converter, a liquid medium-slurry pressure converter and a hydraulic accumulator, wherein the hydraulic station is connected with the oil-liquid medium pressure converter through an electromagnetic valve, the hydraulic station is connected with the hydraulic accumulator, the oil-liquid medium pressure converter is connected with a liquid medium inlet of the liquid medium-slurry pressure converter, the oil-liquid medium pressure converter is also connected with a control end of the electromagnetic valve, the hydraulic accumulator is also connected with the oil-liquid medium pressure converter, and the liquid medium-slurry pressure converter comprises a stretchable rubber pipe, a slurry conveying cavity, a slurry converter body, a slurry inlet, a low-pressure slurry supply system and a mold gas cleaning system The hydraulic converter comprises a converter body, a slurry outlet, a slurry conveying cavity, a stretchable rubber pipe, a liquid medium cavity and a liquid medium cavity, wherein the converter body is internally provided with the slurry conveying cavity, one end of the slurry conveying cavity is communicated with a slurry inlet, the other end of the slurry conveying cavity is communicated with the slurry outlet, the stretchable rubber pipe is also internally provided with the stretchable rubber pipe, the stretchable rubber pipe is filled with a liquid medium and is connected with an oil-liquid medium pressure converter through the liquid medium inlet, the oil-liquid medium pressure converter comprises an oil-liquid converter body, a hydraulic oil cavity, an oil cylinder, a connected piston, a medium cylinder and a liquid medium cavity, one end of the oil-liquid converter body is provided with the hydraulic oil cavity, the other end of the oil-liquid converter body is provided with the liquid medium cavity, the middle part of the oil-liquid converter body is provided with the connected piston, one end of the connected piston is blocked with the hydraulic oil cavity through the oil cylinder, and the other end of the connected piston is blocked with the liquid medium cavity through the medium cylinder, the low-pressure slurry supply system comprises a slurry supply pipeline, a diaphragm pump, a first air-control ball valve and a second air-control ball valve which are connected with a low-speed slurry stirring barrel, the diaphragm pump is connected with the low-speed slurry stirring barrel through the slurry supply pipeline, the diaphragm pump is connected with a slurry inlet of a liquid medium-slurry pressure converter through the first air-control ball valve, the low-speed slurry stirring barrel is also connected with a slurry inlet of the liquid medium-slurry pressure converter through the second air-control ball valve, a slurry outlet of the liquid medium-slurry pressure converter is connected with a mold, the mold gas cleaning system comprises a gas source, a gas source processor and a gas pipe, the gas source is connected with the gas source processor, and the gas source processor is connected with a mold gas washing inlet of the mold through the gas pipe.

Further preferred, still include frame bearing structure, frame bearing structure includes left side stand, right side stand, entablature, bottom end rail, underframe frame, left side stand, right side stand are all fixed in on the underframe frame, still fix through entablature, bottom end rail between left side stand, the right side stand.

Further preferably, the die comprises a left die and a right die, and the left die and the right die are fixed with the upper cross beam in a sliding mode through the mounting frame.

Further preferably, the mold is a porous resin mold.

Further preferably, still including the mould mechanism that opens and shuts, the mould mechanism that opens and shuts includes gear motor, connecting rod, crank, rod end cylinder, gear motor is fixed in on the left side stand, gear motor's output and articulate one end are connected, the articulate other end is connected with the one end of connecting rod, the other end tip of connecting rod is equipped with the rod end cylinder, the rod end cylinder is connected with the left side mould.

Further preferred, still include hydraulic locking system, hydraulic locking system still with high-pressure slip casting headtotail, hydraulic locking system includes rotatory hydro-cylinder, closed master cylinder, back shaft, locking dish, the locking dish is close to left side die holding, the back shaft is installed in the middle part of the locking dish, the one end of rotatory hydro-cylinder is fixed in on the underframe frame, the other end and the closed master cylinder of rotatory hydro-cylinder are fixed, closed master cylinder is installed towards the back shaft.

Further preferred, still include mould washing clean system, mould washing clean system includes electronic self priming pump, filter, water pipe, joint, an end connection clear water of electronic self priming pump, the model washing entry linkage of leading to pipe and mould behind another termination filter of electronic self priming pump.

Further preferably, the low-speed mud agitator includes gear motor, agitator motor, stirring rake, mud barrel body for the drive, agitator motor is connected with gear motor for the drive, gear motor passes through the shaft coupling for the drive and is connected with the stirring rake, the stirring rake stretches into in the mud barrel body.

Further preferably, the automatic slurry filling device further comprises an electric control cabinet, and the electric control cabinet is electrically connected with the low-speed slurry stirring barrel, the high-pressure slurry filling system, the low-pressure slurry supply system and the hydraulic locking system.

Preferably, after the liquid medium is pressurized, the rubber tube is stretched to deform and extrude the slurry conveying cavity, and the extruded slurry conveying cavity is of a structure with a narrow middle part and wide two ends.

(III) advantageous effects

The utility model provides a gas-washing high-pressure slip casting system which has the following beneficial effects:

1. the low-speed slurry stirring barrel is used for storing the slurry and continuously stirring the slurry, so that the slurry is prevented from precipitating, and the slurry meets the use requirement; the low-pressure slurry supply system injects slurry into a mold cavity to complete mold filling; the high-pressure grouting system changes the slurry in the mold cavity into 4Mpa high-pressure slurry, the pressure difference between the slurry and the mold is improved, so that the moisture in the slurry quickly enters the mold and is discharged through the pores of the mold, and a blank is quickly molded.

2. The utility model adopts the design of structures such as a hydraulic station, an oil-liquid medium pressure converter, a liquid medium-mud pressure converter and the like, and pressurizes by hydraulic oil, and then realizes the pressure conversion between oil-liquid medium-mud, thereby realizing the pressurization of the mud in a mould, improving the pressure difference between the mud and the mould and further increasing the yield.

3. The mud pressure of the mould can reach 4Mpa, and the positive pressure area of the large disc product can reach 0.25m²Therefore, the mold can be kept not to be opened by the mold clamping force of about 100 tons, and the hydraulic locking system is designed to complete mold clamping by utilizing a matching structure of the rotary oil cylinder, the closed main oil cylinder, the supporting shaft and the locking disc, so that the mold clamping force of more than or equal to 100 tons can be provided for the mold.

4. In the die closing action of the utility model, the end part of the connecting rod is provided with the rod end cylinder which is a short stroke cylinder, when the crank reaches the right limit position, the left die and the right die are not contacted, a gap of 3-5mm is also arranged between the dies, and the piston rod of the rod end cylinder at the end part of the connecting rod extends out to complete the final die closing action. Therefore, the operation speed of the crank connecting rod can be increased, and the mould can not be damaged due to collision between the two moulds.

5. The mould washing and cleaning system drains water from the inner hole of the mould to the mould cavity, and washes small-particle pug in the forming process from the mould.

6. The mould air cleaning system of the utility model uses compressed air to discharge residual moisture in the mould, thus being beneficial to the next forming.

7. After the liquid medium is pressurized, the rubber tube is stretched to deform and extrude the slurry conveying cavity, the extruded slurry conveying cavity is of a structure with a narrow middle part and wide two ends, the structure design can realize the purpose of applying pressure to the slurry in the whole die by applying pressure to the slurry with small area, in addition, the structure can better control the application of pressure to the slurry, the pressure application effect is also best, and the rejection rate is greatly reduced.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the utility model.

Drawings

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

FIG. 2 is a schematic view of a model gas wash inlet of the present invention;

FIG. 3 is a schematic structural diagram of the mold opening and closing mechanism of the present invention;

FIG. 4 is a schematic structural view of the mold opening and closing mechanism in another direction of the present invention;

FIG. 5 is a schematic structural diagram of a mold opening and closing mechanism during mold opening of the present invention;

FIG. 6 is a front view showing the relationship between the position of the closed master cylinder and the position of the periphery of the closed master cylinder after the closing of the dies;

FIG. 7 is a schematic diagram of the oil-to-liquid medium pressure transducer construction of the present invention;

FIG. 8 is a schematic diagram of the construction of the fluid medium-mud pressure transducer of the present invention;

FIG. 9 is a block diagram of the overall structure of the present invention;

in the figure: 1. a right upright post; 2. an upper cross beam; 3. a left side column; 4. a reduction motor; 5. a crank; 6. A bottom frame; 7. a connecting rod; 8. closing the main oil cylinder; 9. rotating the oil cylinder; 10. a lower cross beam; 11. a left side mold; 12. a right side mold; 13. a support shaft; 14. a rod end cylinder; 15. a hydraulic oil chamber; 16. an oil cylinder; 17. a conjoined piston; 18. a medium cylinder; 19. a liquid medium chamber; 20. a slurry inlet; 21. a stretchable rubber tube; 22. a liquid medium; 23. a slurry delivery chamber; 24. a liquid medium inlet; 25. a slurry outlet A; 26. a slurry outlet B; 27. a diaphragm pump; 28. a hydraulic station; 29. a slurry barrel body; 30. a stirring paddle; 31. a coupling; 32. a drive reduction motor; 33. a stirring motor; 34. a model water washing inlet; 35. a model slurry inlet; 36. a model gas washing inlet; 37. a low-speed slurry stirring barrel; 38. a low pressure slurry supply system; 39. a mold opening and closing mechanism; 40. a high pressure grouting system; 41. an oil-to-liquid medium pressure transducer; 42. a liquid medium-mud pressure transducer; 43. a hydraulic accumulator; 44. a hydraulic locking system; 45. a mold water cleaning system; 46. a mold gas purge system; 47. an electric self-priming pump; 48. a filter; 49. a water pipe; 50. a gas source; 51. an air source processor;

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by a person of ordinary skill in the art without creative efforts based on the embodiments of the present invention belong to the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, are used in the orientations and positional relationships indicated in the drawings, which are based on the orientations and positional relationships indicated in the drawings, and are used for convenience of description and simplicity of description, but do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

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

Referring to fig. 1-9, the present invention provides a technical solution: a gas-washing high-pressure grouting forming system comprises a mold, a low-speed slurry stirring barrel 37, a high-pressure grouting system 40, a low-pressure slurry supply system 38, a hydraulic locking system 44 and a framework supporting structure.

As shown in fig. 1-3, the frame support structure includes a left side column 3, a right side column 1, an upper beam 2, a lower beam 10 and a bottom frame 6, the left side column 3 and the right side column 1 are fixed on the bottom frame 6, the left side column 3 and the right side column 1 are fixed with each other through the upper beam 2 and the lower beam 10, the mold includes a left side mold 11 and a right side mold 12, and the left side mold 11 and the right side mold 12 are fixed with the upper beam 2 through a mounting frame in a sliding manner.

As shown in fig. 1-2, the low-speed slurry mixing tank 37 includes a driving gear motor 32, a mixing motor 33, a mixing paddle 30, and a slurry tank 29, wherein the mixing motor 33 is connected to the driving gear motor 32, the driving gear motor 32 is connected to the mixing paddle 30 through a coupling 31, and the mixing paddle 30 extends into the slurry tank 29.

When the stirring device works, the stirring motor 33 drives the driving speed reducing motor 32 to work, the driving speed reducing motor 32 drives the stirring paddle 30 to rotate through the coupler 31, and the inside of the slurry barrel body 29 is continuously stirred in a rotating mode, so that slurry is prevented from being deeply deposited.

As shown in fig. 3, the present invention further includes a mold opening and closing mechanism 39, the mold opening and closing mechanism 39 includes a gear motor 4, a connecting rod 7, a crank 5, and a rod end cylinder 14, the gear motor 4 is fixed on the left upright 3, an output end of the gear motor 4 is connected with one end of the crank 5, the other end of the crank 5 is connected with one end of the connecting rod 7, the rod end cylinder 14 is arranged at the other end of the connecting rod 7, and the rod end cylinder 14 is connected with the left mold 11.

As shown in fig. 4-6, the hydraulic locking system 44 includes a rotary cylinder 9, a closed master cylinder 8, a supporting shaft 13, and a locking disk, the locking disk is installed near the left mold 11, the supporting shaft 13 is installed in the middle of the locking disk, one end of the rotary cylinder 9 is fixed on the bottom frame 6, the other end of the rotary cylinder 9 is fixed with the closed master cylinder 8, and the closed master cylinder 8 is installed facing the supporting shaft 13.

The high-pressure grouting system 40 comprises a hydraulic station 28, an oil-liquid medium pressure converter 41, a liquid medium-mud pressure converter 42 and a hydraulic accumulator 43, wherein the hydraulic station 28 is connected with the oil-liquid medium pressure converter 41 through an electromagnetic valve, the hydraulic station 28 is connected with the hydraulic accumulator 43, the oil-liquid medium pressure converter 41 is connected with the liquid medium inlet 24 of the liquid medium-mud pressure converter 42, the oil-liquid medium pressure converter 41 is further connected with the control end of the electromagnetic valve, and the hydraulic accumulator 43 is further connected with the oil-liquid medium pressure converter 41.

As shown in fig. 7, the oil-liquid medium pressure converter 41 includes an oil-liquid converter body, a hydraulic oil chamber 15, an oil cylinder 16, an integrated piston 17, a medium cylinder 18, and a liquid medium chamber 19, the hydraulic oil chamber 15 is disposed at one end of the oil-liquid converter body, the liquid medium chamber 19 is disposed at the other end of the oil-liquid converter body, the integrated piston 17 is disposed in the middle of the oil-liquid converter body, one end of the integrated piston 17 blocks the hydraulic oil chamber 15 through the oil cylinder 16, and the other end of the integrated piston 17 blocks the liquid medium chamber 19 through the medium cylinder 18.

When the hydraulic station works, the hydraulic station applies pressure to hydraulic oil in the hydraulic oil cavity 15, and further applies pressure to the oil cylinder 16, so that the conjoined piston 17 and the liquid medium cavity 19 are driven to apply pressure to the liquid medium cavity 19, and the liquid medium is pressurized.

As shown in fig. 8, the liquid medium-mud pressure converter 42 includes a stretchable rubber tube 21, a mud conveying cavity 23, a mud converter body, a mud inlet 20, and a mud outlet, the inside of the converter body is provided with the mud conveying cavity 23, one end of the mud conveying cavity 23 is communicated with the mud inlet 20, the other end of the mud conveying cavity 23 is communicated with the mud outlet (a plurality of mud outlets, as shown in fig. 8, the number of mud outlets is 2, which are respectively a mud outlet a (25) and a mud outlet B (26)), the inside of the converter body is further provided with the stretchable rubber tube 21, the stretchable rubber tube 21 is filled with a liquid medium 22, and the stretchable rubber tube 21 is connected with the oil-liquid medium pressure converter 41 through a liquid medium inlet 24.

In operation, the mud enters the mud conveying cavity 23 from the mud inlet 20 and is output from the mud outlet, and after the mud is filled in the whole mud conveying cavity 23, if pressure is applied to the liquid medium, the stretchable rubber tube 21 filled with the liquid medium applies pressure to the mud conveying cavity 23, so that the mud is pressurized.

The low-pressure slurry supply system 38 comprises a slurry supply pipeline connected with the low-speed slurry stirring barrel 37, a diaphragm pump 27, a first pneumatic control ball valve and a second pneumatic control ball valve, wherein the diaphragm pump 27 is connected with the low-speed slurry stirring barrel 37 through the slurry supply pipeline, the diaphragm pump 27 is connected with the slurry inlet 20 of the liquid medium-slurry pressure converter 42 through the first pneumatic control ball valve, the low-speed slurry stirring barrel is also connected with the slurry inlet of the liquid medium-slurry pressure converter through the second pneumatic control ball valve, the slurry outlet of the liquid medium-slurry pressure converter 42 is connected with a mold, and the hydraulic locking system 44 is also connected with the high-pressure grouting system 40.

The die washing system 45 comprises an electric self-sucking pump 47, a filter 48, a water pipe 49 and a connector, wherein one end of the electric self-sucking pump 47 is connected with clean water, and the other end of the electric self-sucking pump 47 is connected with the filter 48 and then is connected with a die washing inlet 34 of a die through the water pipe 49.

The utility model also includes a mold gas purging system 46, the mold gas purging system 46 including a gas source 50, a gas source processor 51, a gas line, a gas source 50 and a gas source processor 51. The air source handler 51 is connected to the mold pattern air purge inlet 36 via an air line.

The working principle is as follows: the raw material of the grouting mud is manually injected into the low-speed mud stirring barrel 37, and the density and the proportion of the grouting mud are finely adjusted in the mud barrel body 29, so that the grouting mud can be used for high-pressure grouting forming. Meanwhile, the low-speed slurry stirring barrel 37 is continuously rotated and stirred to prevent the slurry from being deeply deposited.

The diaphragm pump 27 in the low-pressure slurry supply system 38 extracts slurry from the low-speed slurry mixing tank 37, conveys the slurry to the slurry conveying cavity 23 in the liquid medium-slurry pressure converter 42, conveys the slurry to the inner cavity of the mold which is closed after the slurry is filled through the slurry outlet of the slurry conveying cavity 23, closes the first air-controlled ball valve after the filling time (which can be set through a PLC in an electric control cabinet), and stops conveying the slurry to the liquid medium-slurry pressure converter 42, but the liquid medium-slurry pressure converter 42 is still communicated with the inner cavity of the mold, namely the slurry outlet of the liquid medium-slurry pressure converter 42 is still communicated with the inner cavity of the mold.

The hydraulic station 28 operates to start pressurizing the hydraulic oil in the hydraulic oil chamber 15 in the oil-liquid medium pressure converter 41, while the hydraulic station 28 is filling the hydraulic accumulator 43 with pressure. After the hydraulic oil in the oil-liquid medium pressure converter 41 reaches a certain pressure value, the electromagnetic valve which controls the hydraulic station 28 to be communicated with the oil-liquid medium pressure converter 41 is powered off, the hydraulic station 28 does not provide power for the oil-liquid medium pressure converter 41 any more, and the follow-up pressure in the oil-liquid medium pressure converter 41 is kept to be provided by the hydraulic accumulator 43.

The oil-liquid medium pressure converter 41 transmits the pressure of the hydraulic oil to the liquid medium 22 in the liquid medium cavity 19, the pressure in the liquid medium 22 is increased to the set mud pressure (4Mpa), and the liquid medium 22 transmits the pressure to the mud in the liquid medium-mud pressure converter 42 through the liquid medium-mud pressure converter 42, so that the mud reaches the set pressure. The slurry in the fluid medium-to-slurry pressure transducer 42 is connected to the slurry in the mold and pressure is also transmitted to the slurry in the mold.

Due to the existence of high pressure, the moisture in the slurry is accelerated to enter the porous resin mold, the moisture is discharged out of the mold through a capillary network in the porous resin mold, the moisture content of the slurry in the mold is rapidly reduced, and after the slurry reaches a certain moisture content (the moisture content of a green body is not directly measured but is controlled by pressurization time because the slurry performance, the pressurization pressure and the mold performance are consistent), the slurry is changed into a mud blank with a certain shape under the action of the mold.

After the forming is finished, the second pneumatic control ball valve between the liquid medium-slurry pressure converter 42 and the stirring barrel is opened, then the die, the liquid medium-slurry pressure converter 42 and the low-speed slurry stirring barrel are communicated, and the pressure in the die and the pipeline is released.

Further, the piston rod of the closed main oil cylinder 8 retracts, after the piston rod retracts to the final position, the piston rod of the rotary oil cylinder 9 retracts, the closed main oil cylinder 8 finishes swinging in a vertical plane under the action of the rotary oil cylinder 9, and a movable space of the support shaft 13 after a mold is opened is avoided. After the piston rod of the rotary oil cylinder 9 retracts to the lowest position, the main oil cylinder 8 is closed to completely avoid the activity space of the support shaft 13.

And the electromagnetic valve for controlling the communication of the compressed air and the left side die 11 is electrified, the compressed air enters the left side die 11, and the die is separated from the product through the resin capillary holes. After a certain time of ventilation, the speed reducing motor 4 connected with the crank 5 starts to work, the speed reducing motor drives the crank 5 to act, the crank 5 drives the connecting rod 7 to act, the connecting rod 7 drives the left die to start to move leftwards, and finally the left die reaches the left limit point of the crank 5, so that the die opening action is completed, as shown in fig. 5.

The safety door is opened, the product blank is manually taken out of the right side die 12 by using the sucker clamp, and the safety door is closed.

After the product is taken out, electric self-priming pump 47 starts, and the clear water gets into filter 48 from the self-priming pump, and in the water pipe got into the mould of both sides again, the capillary micropore through the resin mold discharged from the shaping working face of mould, the completion was to the washing of mould working face. After a certain time of cleaning, the electric self-priming pump 47 is turned off.

After the die working surface is cleaned, the die air cleaning system 46 controls the compressed air to be electrified with the electromagnetic valves communicated with the dies on the two sides, and the compressed air enters the dies on the two sides and discharges the moisture in the resin capillary holes.

After the mold is drained, the speed reducing motor 4 connected with the crank 5 starts to work again, but the rotating direction of the speed reducing motor 4 is opposite to that before, the speed reducing motor 4 drives the crank 5, the crank 5 drives the connecting rod 7, the connecting rod 7 drives the mold on the left side to start to move rightwards, and finally the right limit point of the crank 5 is reached, the piston of the rod end cylinder 14 at the end part of the connecting rod 7 extends out, the molds on the left side and the right side are pressed together, and the mold closing action is finished.

And the piston rod of the rotary oil cylinder 9 extends out to push the closed main oil cylinder 8 to a closed jacking position, and after the piston rod of the rotary oil cylinder 9 reaches an upper limit position, the piston rod of the closed main oil cylinder 8 is just concentric with the support shaft 13 on the left side of the mold.

After the closed main oil cylinder 8 reaches the closed jacking position, the piston rod extends out to be in contact with the supporting shaft 13, and meanwhile, the mould is jacked. The tail part of the closed main oil cylinder 8 is attached to the left upright post 3, the closed main oil cylinder 8 keeps the piston rod extending thrust, and mold clamping force larger than or equal to 100 tons is provided for the mold.

This completes a production cycle.

In another embodiment of the utility model, after the liquid medium is pressurized, the stretched rubber tube deforms to extrude the slurry conveying cavity, and the extruded slurry conveying cavity 23 is of a structure with a narrow middle part and two wide ends, so that the pressure applied to the slurry can be better controlled through the design of the structure.

In another embodiment of the present invention, the mold is a porous resin mold.

In another embodiment of the present invention, in order to improve automation, the present invention further comprises an electric control cabinet, and the electric control cabinet is electrically connected to the low-speed slurry mixing tank 37, the high-pressure grouting system 40, the low-pressure slurry supply system 38, and the hydraulic locking system 44.

The utility model has the following beneficial effects:

1. one set of resin mold can be used for 1.5 ten thousand times, and the cost of the product mold is 0.3-0.5 yuan/piece. The cost of the traditional die is 0.5-0.6 yuan/piece, and the use cost of the die is reduced.

2. The service life of the traditional die is about 40 times, and 375 dies are needed for producing 1.5 ten thousand products. Reduces the consumption of raw materials of the die and is more environment-friendly.

3. In the production process, workers do not need to move the die, and the labor intensity of the workers is greatly reduced.

4. The production process is controlled by a PLC in the electric control cabinet, the technological parameters of the product are stably controlled, the consistency of the product is high, and the yield is ensured.

5. The used mould does not need to be dried, and the heat consumption is reduced.

6. The same order is finished, the number of the moulds is less, the floor area of a factory is reduced, and the land utilization rate of the factory is higher.

7. The production process is controlled by a PLC in the electric control cabinet, workers can be put on duty only by simple training without understanding the process, and the problem of factory recruitment is solved.

In the description of the present invention, it is to be understood that the indicated orientations or positional relationships are based on the orientations or positional relationships shown in the drawings, which are merely for convenience in describing the present invention and for simplicity in description, and are not intended to indicate or imply that the indicated devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

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

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides a gas wash high pressure slip casting system, includes the mould, its characterized in that: the high-pressure grouting system (40) comprises a hydraulic station (28), an oil-liquid medium pressure converter (41), a liquid medium-mud pressure converter (42) and a hydraulic energy accumulator (43), wherein the hydraulic station (28) is connected with the oil-liquid medium pressure converter (41) through an electromagnetic valve, the hydraulic station (28) is connected with the hydraulic energy accumulator (43), the oil-liquid medium pressure converter (41) is connected with a liquid medium inlet (24) of the liquid medium-mud pressure converter (42), the oil-liquid medium pressure converter (41) is also connected with a control end of the electromagnetic valve, the hydraulic energy accumulator (43) is also connected with the oil-liquid medium pressure converter (41), the liquid medium-mud pressure converter (42) comprises a stretchable rubber pipe (21), a mud conveying cavity (23), a liquid-mud converter body, a mud inlet (20) and a mud outlet, the mud conveying cavity (23) is arranged inside the converter body, one end of the mud conveying cavity (23) is communicated with the mud inlet (20), the other end of the mud conveying cavity (23) is communicated with the mud outlet, the stretchable rubber pipe (21) is further arranged inside the converter body, liquid media (22) are filled inside the stretchable rubber pipe (21), the stretchable rubber pipe (21) is connected with an oil-liquid medium pressure converter (41) through a liquid medium inlet (24), and the oil-liquid medium pressure converter (41) comprises an oil-liquid converter body, a hydraulic oil cavity (15), an oil cylinder (16), a connected piston (17), The hydraulic converter comprises a medium cylinder (18) and a liquid medium cavity (19), wherein a hydraulic oil cavity (15) is arranged at one end of an oil converter body, the liquid medium cavity (19) is arranged at the other end of the oil converter body, a connected piston (17) is arranged in the middle of the oil converter body, one end of the connected piston (17) blocks the hydraulic oil cavity (15) through an oil cylinder (16), the other end of the connected piston (17) blocks the liquid medium cavity (19) through the medium cylinder (18), a low-pressure slurry supply system (38) comprises a slurry supply pipeline connected with a low-speed slurry stirring barrel (37), a diaphragm pump (27), a first air-controlled ball valve and a second air-controlled ball valve, the diaphragm pump (27) is connected with the low-speed slurry stirring barrel (37) through the slurry supply pipeline, and the diaphragm pump (27) is connected with a slurry inlet (20) of a liquid medium-slurry pressure converter (42) through the first air-controlled ball valve, the low-speed mud agitator (37) is also connected with the mud inlet (20) of the liquid medium-mud pressure converter (42) through a second pneumatic control ball valve, the mud outlet of the liquid medium-mud pressure converter (42) is connected with the mould, the mould gas cleaning system (46) comprises a gas source (50), a gas source processor (51) and a gas pipe, the gas source (50) is connected with the gas source processor (51), and the gas source processor (51) is connected with the model gas washing inlet (36) of the mould through the gas pipe.

2. The air-wash high-pressure slip casting system according to claim 1, wherein: still include frame bearing structure, frame bearing structure includes left side stand (3), right side stand (1), entablature (2), bottom end rail (10), underframe (6), on left side stand (3), right side stand (1) all were fixed in underframe (6), still fix through entablature (2), bottom end rail (10) between left side stand (3), the right side stand (1).

3. The air-wash high-pressure slip casting system according to claim 2, wherein: the die comprises a left die (11) and a right die (12), wherein the left die (11) and the right die (12) are fixed with the upper cross beam (2) in a sliding mode through the mounting frame.

4. The air-wash high-pressure slip casting system according to claim 3, wherein: the mold is a porous resin mold.

5. The air-wash high-pressure slip casting system according to claim 3, wherein: still including opening and shutting die mechanism (39), die mechanism (39) opens and shuts includes gear motor (4), connecting rod (7), crank (5), rod end cylinder (14), gear motor (4) are fixed in on left side stand (3), the output of gear motor (4) is connected with the one end of crank (5), the other end of crank (5) is connected with the one end of connecting rod (7), the other end tip of connecting rod (7) is equipped with rod end cylinder (14), rod end cylinder (14) are connected with left side mould (11).

6. The air-wash high-pressure slip casting system according to claim 3, wherein: still include hydraulic pressure locking system (44), hydraulic pressure locking system (44) still are connected with high-pressure slip casting system (40), hydraulic pressure locking system (44) include rotatory hydro-cylinder (9), closed master cylinder (8), back shaft (13), locking dish, the locking dish is close to left side mould (11) installation, back shaft (13) are installed in locking dish middle part, the one end of rotatory hydro-cylinder (9) is fixed in on underframe frame (6), the other end and the closed master cylinder (8) of rotatory hydro-cylinder (9) are fixed, closed master cylinder (8) are installed towards back shaft (13).

7. The air-wash high-pressure slip casting system according to claim 1, wherein: still include mould washing clean system (45), mould washing clean system (45) includes electronic self priming pump (47), filter (48), water pipe (49), joint, the one end of electronic self priming pump (47) connects the clear water, be connected with the model washing entry (34) of mould through water pipe (49) behind the other end connection filter (48) of electronic self priming pump (47).

8. The air-wash high-pressure slip casting system according to claim 1, wherein: low-speed mud agitator (37) are including drive with speed reducer (32), agitator motor (33), stirring rake (30), mud staving (29), agitator motor (33) are connected with drive with speed reducer (32), drive is connected with stirring rake (30) through shaft coupling (31) with speed reducer (32), stirring rake (30) stretch into in mud staving (29).

9. The air-wash high-pressure slip casting system according to claim 1, wherein: the device is characterized by further comprising an electric control cabinet, wherein the electric control cabinet is electrically connected with the low-speed slurry stirring barrel (37), the high-pressure grouting system (40), the low-pressure slurry supply system (38) and the hydraulic locking system (44).

10. The air-wash high-pressure slip casting system according to claim 1, wherein: after the liquid medium is pressurized, the stretching rubber tube (21) deforms and extrudes the slurry conveying cavity (23), and the extruded slurry conveying cavity (23) is of a structure with a narrow middle part and wide two ends.

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