CN100335207C

CN100335207C - Die-casting device and vacuum process

Info

Publication number: CN100335207C
Application number: CNB2005100817422A
Authority: CN
Inventors: 久保田正光
Original assignee: Toshiba Machine Co Ltd
Current assignee: Shibaura Machine Co Ltd
Priority date: 2004-04-20
Filing date: 2005-04-20
Publication date: 2007-09-05
Anticipated expiration: 2025-04-20
Also published as: KR100715386B1; CN1701878A; KR20060047239A

Abstract

The present invention provides a mold casting device which can manufacture high-quality molded products and utilizes an oxygen displacement mold casting method. By using the oxygen supply device (80) to fill the mold cavity (C) and the injection sleeve (16) with oxygen, and after purging the mold cavity (C) and the injection sleeve (16) with oxygen, make the injection into the mold cavity (C) Parts that can enter the outside air, such as the auxiliary decompression tank (TB) and the third on-off valve (SV) for decompression and exhaust from the fixed mold flow path (2c) and the moving mold flow path (3c), and the The main decompression tank (TA) and the first on-off valve (MV) for decompression in the mold cavity operate in parallel at the same time.

Description

Die casting device and reduced pressure casting method

Technical field

The reduced pressure casting method that the present invention relates to die casting device (die casting machine) and be used for die casting device.

Particularly, the present invention relates to be suitable for the die casting device and the reduced pressure casting method in this die casting device of replacement of oxygen die casting.

Background technology

As the reason that the reliability that for example causes with the deviation of the quality of aluminum dipping form casting goods owing to the die casting goods reduces, be owing in the die casting goods, contain gas etc.Promptly, under high speed, condition of high voltage, inject, with the metallic solution (motlten metal) of filling (cast) in the shot sleeve for example aluminum metal solution in the die cavity of shot sleeve and mould, become turbulent flow, and having air and water vapour etc. is filled in the die cavity of gas mould, these gases form bubble, make in the die casting goods and produce the hole, thereby the quality of die casting goods is reduced.

In order to overcome the problems referred to above, known technology is: utilization is decompressed to the die casting machine of the vacuum mold casting of vacuum state in will the die cavity with respect to the mould of extraneous air sealing and casts, thereby, can suppress the gas that contains in the die casting goods in the die cavity, reduce because the gas that contains in the die casting goods causes the deviation of die casting product property.(for example with reference to patent documentation 1)

In the die casting machine that uses this vacuum mold casting, be necessary to make the low-down pressure that reduces pressure at short notice in the die cavity of mould.Below, narrate its reason.

For example, be connected the decompression of carrying out in the die cavity by being decompressed to the relief groove of being scheduled to low pressure with the die cavity of sealing, because the pressure differential in relief groove and the die cavity is very big scope, therefore can reduce pressure hastily, along with this pressure differential diminishes, owing to the flow velocity reduction of the gas of discharging from die cavity, reaching desired pressure needs the very long time.Die casting machine is being necessary to make in the die cavity decompression under the state of sleeve supplying melting metal (metallic solution), if the needed time of decompression is elongated, then may cools off in sleeve and solidify at the motlten metal of supply sleeve before die cavity is filled.

In addition, in the die cavity of the mould by the vacuum mold casting, even from for example 1.01325 * 10 ⁵The atmosphere pressure energy of Pa for example reduces pressure 5.33289 * 10 ³Low-down pressure about Pa, gases such as still more residual a little air and water vapour in die cavity.This die casting goods that contain residual gas even defective does not take place the die casting goods in heat treatments such as T6 processing, also can form minute bubbles under the hot conditions when welding, and become the reason of the defective of weld part in the die casting goods.

For preventing to produce the defective of die casting goods owing to gas residual in the die cavity, known method is: with the gas replacement of oxygen in the die cavity of mould, make motlten metal and oxygen react (making oxidation), produce bubble in the die casting goods that prevent to cast, promptly so-called replacement of oxygen die casting (for example with reference to patent documentation 2 and 3).

For example, be under the situation of aluminium at motlten metal, aluminium and oxygen react, and generate alundum (Al (aluminium oxide) Al ₂O ₃Particulate.

No. 2,785,448, [patent documentation 1] United States Patent (USP)

[patent documentation 2] spy opens flat 10-113757 communique

[patent documentation 3] spy opens flat 9-1306 communique

Summary of the invention

The replacement of oxygen die casting, the problem of existence is; If the amount of the oxygen of displacement is many, then make a lot of motlten metal oxide of generation in the die casting goods, the quality of die casting goods is reduced.For example contain a lot of aluminium oxide (Al ₂O ₃) aluminum dipping form casting goods in, the characteristic of die casting goods such as ductility or quality reduce.In addition, if the amount of oxygen of displacement is many, then residual not with the oxygen of molten reactant metal, make in the die casting goods because oxygen produces bubble.

On the other hand, even mould etc. reduce pressure under sealing state, also be difficult to make the air outside of invading mould inner mould chamber and/or sleeve from the hermetic unit leakage not have fully, the gas in the die cavity that is difficult for forming in mould is replaced fully with oxygen.Owing to making in the die casting goods, residual gas except that oxygen in die cavity produces bubble.

The objective of the invention is, a kind of die casting device (die casting machine) and reduced pressure casting method are provided, described apparatus and method make gases such as the moisture of reason of the internal flaw that becomes casting product and nitrogen not remain in the die cavity of mould and lead in the gas intrusion path of die cavity, guarantee die cavity and the gas that leads to die cavity invaded in the path and can use replacement of oxygen, and, can shorten and will be decompressed to the time of predetermined pressure in the die cavity.

A kind of die casting device is provided according to a first aspect of the invention, and this device is to fill the die casting device that metallic solution is made the die casting goods in die cavity, and comprising: (a) regulation is filled first mould and second mould of the die cavity of metallic solution; (b) first decompressor; (c) oxygen feedway; (d) but to install and make above-mentioned first decompressor or above-mentioned oxygen feedway in above-mentioned first mould and/or above-mentioned second mould be the first open and close valve device of connected state or non-connected state with above-mentioned die cavity; (f) be communicated with and on the relative side of a side that is communicated with above-mentioned die cavity, have the shot sleeve of the supply port that above-mentioned metallic solution is poured into a mould with above-mentioned die cavity; (g) have stopper head within the inner core that is embedded into this shot sleeve, and the metallic solution that will pour into a mould from above-mentioned supply port is to the injection piston device of above-mentioned cavity injection in above-mentioned shot sleeve with moving freely; (h) the injection cylinder device that this injection piston device is driven; (i) because second decompressor that is reduced pressure at least one gap in the gap of gap, above-mentioned second mould and the above-mentioned first open and close valve device between the gap (gap) above-mentioned first mould that can invade extraneous air from the outside of above-mentioned die cavity and/or above-mentioned shot sleeve, gap (gap), above-mentioned shot sleeve and above-mentioned stopper head in above-mentioned second mould.

In the die casting device of said structure, carry out following operation.

(1) in above-mentioned shot sleeve, begin casting metal solution from above-mentioned supply port after, to above-mentioned cast finish with first speed by shot sleeve till first injection is carried out in the above-mentioned film chamber of above-mentioned metallic solution during, the above-mentioned first open and close valve device makes above-mentioned oxygen feedway be communicated with above-mentioned die cavity for opening state, the above-mentioned second open and close valve device is for opening state, make and in above-mentioned die cavity and above-mentioned shot sleeve, to supply with oxygen and emit, make in the above-mentioned die cavity and be full of oxygen in the above-mentioned shot sleeve and discharge oxygen gas in addition from above-mentioned supply port from above-mentioned oxygen feedway.

(2) fill above-mentioned oxygen in above-mentioned die cavity and in the above-mentioned shot sleeve after, make the above-mentioned second open and close valve device for closing state, finish the filling of above-mentioned oxygen.

(3) after the above-mentioned second open and close valve device becomes the state of closing, to with second speed by above-mentioned injection piston till the above-mentioned die cavity of above-mentioned metallic solution begins second injection, the above-mentioned first open and close valve device utilizes above-mentioned first decompressor to reducing pressure in the above-mentioned die cavity and in the above-mentioned shot sleeve for opening state by above-mentioned first open and close valve of opening state.

(4) the above-mentioned second open and close valve device is for after closing state, and during till above-mentioned die cavity taking-up die casting goods, above-mentioned the 3rd open and close valve device reduces pressure to above-mentioned at least one gap by above-mentioned second decompressor for opening state.

Preferably, this die casting device has control device.

This die casting device carries out following control operation.

(1) by above-mentioned plunger assembly move from above-mentioned supply port to above-mentioned shot sleeve in behind the beginning casting metal solution, make the action of above-mentioned second open and close valve device and the above-mentioned first open and close valve device, make above-mentioned oxygen feedway be communicated with above-mentioned die cavity, thereby make in above-mentioned die cavity and the above-mentioned shot sleeve and be full of oxygen, and, emit oxygen by making, make in the above-mentioned die cavity and the discharge of the gas beyond the oxygen in the above-mentioned shot sleeve from above-mentioned supply port.

(2) after the cast of above-mentioned metallic solution finishes,, above-mentioned injection piston device is moved with first speed, and begin and to be cast in metallic solution in the above-mentioned shot sleeve to above-mentioned cavity injection by driving above-mentioned injection cylinder device.

(3) make the above-mentioned second open and close valve device for closing state, stop from above-mentioned oxygen feedway in above-mentioned die cavity and the filling of the oxygen in the above-mentioned shot sleeve handle.

(4) behind the shutoff operation of the above-mentioned second open and close valve device, arrive with second speed by till above-mentioned injection piston device is before the above-mentioned die cavity start injection of above-mentioned metallic solution, make the above-mentioned first open and close valve device for opening state, and utilize above-mentioned first decompressor to reducing pressure in the above-mentioned die cavity and in the above-mentioned shot sleeve by the above-mentioned first open and close valve device of opening state.

(5) behind the shutoff operation of the above-mentioned second open and close valve device, till taking-up die casting goods, make above-mentioned the 3rd open and close valve device for opening state, utilize above-mentioned second decompressor that the part that can invade extraneous air from said external is reduced pressure.

More preferably, this die casting device has the position sensor of the position of detecting above-mentioned injection piston, above-mentioned control device will carry out the translational speed that time diffusion is tried to achieve injection piston according to the position probing value of above-mentioned position sensor, thereby judge the situation that above-mentioned injection piston device is injected with above-mentioned first speed and above-mentioned second speed.

A kind of reduced pressure casting method that is used for die casting device is provided according to a second aspect of the invention, this method is the reduced pressure casting method that is used for making by the replacement of oxygen die casting die casting device of die casting goods, comprise following operation: after (a) in shot sleeve, beginning casting metal solution from supply port, finish and injection piston moved with first speed above-mentioned metallic solution is expelled to by till in the die cavity of defined in the mould to above-mentioned cast, make in above-mentioned die cavity and the above-mentioned shot sleeve and be full of oxygen, and emit from above-mentioned supply port, make in the above-mentioned die cavity and above-mentioned shot sleeve in be full of and discharge the oxygen blow operation of oxygen gas in addition with oxygen; (b) behind this oxygen end-of-fill, to make above-mentioned injection piston with second speed move begin to be expelled to above-mentioned metallic solution before the above-mentioned die cavity till, in the above-mentioned die cavity and the first decompression operation that reduces pressure in the above-mentioned shot sleeve; And (c) behind above-mentioned oxygen end-of-fill, before taking out to the die casting goods till, the second decompression operation that the part that can invade extraneous air from the outside from above-mentioned die cavity and/or above-mentioned sleeve in the above-mentioned die casting device is reduced pressure.

According to the present invention, utilize first decompressor by decompression operation to applying decompression exhaust in the die cavity in the mould, and utilize second decompressor by decompression operation, will become in the die cavity, the gases such as extraneous air from the outside of sleeve and/or die cavity of the harm of the die casting in the shot sleeve etc. in making discharge.Consequently can make high-quality die casting goods.

In addition,, provide an amount of oxygen, can make high-quality die casting goods by decompression replacement of oxygen die casting according to the present invention.

In addition,,, can not cause the metallic solution temperature reduction significantly of the cast in shot sleeve, can make high-quality die casting goods owing to a series of action can be carried out continuously and in short time according to the present invention.

According to the present invention, has the effect that prolongs the life-span be used to make the die casting goods.

In the present invention, be full of with oxygen in the enclosure space that the die casting that will contain the die casting device of the die cavity in the mould is used in handling, then because from carrying out exhaust by second decompression from the stream that first mould for example forms between the inner peripheral surface of the groove of move moulds stream and the stopper head that for example move moulds of fixed mould stream, second mould of fixed mould and sleeve by second decompressor, carry out replacement of oxygen so can guarantee each corner in containing the enclosure space of die cavity, in addition, guarantee also can use replacement of oxygen in the gas intrusion path.

In addition in the present invention, in the enclosure space that the die casting of guaranteeing to contain the die casting device of die cavity is used in handling also with behind the replacement of oxygen, by with second decompressor to continuing exhaust in the above-mentioned enclosure space, the gas that makes extraneous air etc. become the harm in the die casting manufacturing can not invade in the die cavity, in the sleeve etc. in.

In addition, in the present invention,, when shortening the needed time of reducing pressure, can make also that remaining oxygen is in the extreme less by the filling of replacement of oxygen method and in die cavity because second decompressor and first decompressor move simultaneously.

Description of drawings

Fig. 1 is the structure chart of the described die casting device of expression embodiment of the present invention.

Fig. 2 is in the die casting device that illustrates of Fig. 1, with fixed mould with to move moulds be the partial enlarged drawing at center, when being expression t0～action diagram of the die casting device of t3 till constantly.

Fig. 3 is the process chart (flow chart) that the operation of the die casting device of Fig. 1 explanation is represented with time series.

Fig. 4～Figure 12 is the mode of operation figure of the major part of the die casting device in explanation each engineering illustrated in fig. 3.

The specific embodiment

Preferred implementation with reference to description of drawings die casting device of the present invention (die casting machine) and reduced pressure casting method.

The structure of die casting device

The structure of the die casting device of an embodiment of the present invention is described.

Fig. 1 is the profile of structure of the mold periphery of the related die casting device of expression an embodiment of the present invention.

The die casting device 1 of present embodiment comprises: fixed mould 2, with respect to fixed mould 2 move move moulds 3, injection device 10, controller 30, main relief groove TA, assisted decompression groove TB, stop valve (check-valves) 60 and oxygen feedway 80.

Controller 30 is the parts of various controls of carrying out the die casting device 1 of following detailed description, by use arithmetic processing apparatus for example computer realize.

Injection device 10 comprises oil hydraulic cylinder 11, piston rod 12, connector 13, injection piston 17 and shot sleeve 16.

Oil hydraulic cylinder 11 drives by the oil (action oil) of predetermined pressure, in state shown in Figure 1, makes piston rod 12 move left and right.

Injection piston 17 comprises plunger rod 14 and stopper head 15.

Connector 13 connects piston rod 12 and the plunger rod 14 that is connected with oil hydraulic cylinder 11.

Shot sleeve 16 is made by cylindric heat-resisting, pressure-proof components, is provided with supply port 16h in shot sleeve 16, and it is used for casting metal solution (dissolution of metals) in the inner core of the shot sleeve 16 of mobile plunger head 15.The opposition side of the supply port 16h of shot sleeve 16 is communicated with die cavity C, and this die cavity is fixing in fixed mould 2, and is stipulated with moving moulds by fixed mould 2.

The front end of plunger rod 14 is connected with stopper head 15, and stopper head 15 embeds in the inner core of shot sleeve 16 with moving freely.

Extraneous air with respect to the outside between the inner peripheral surface of the outer peripheral face of stopper head 15 and shot sleeve 16 is sealed to airtight conditions.Utilize stopper head 15 to move to the place ahead of die cavity C side, shot sleeve 16 is sealed with respect to the outside by supply port 16h.

Fig. 2 be in the die casting device 1 that illustrates of Fig. 1 fixed mould 2, move moulds 3 and the periphery enlarged drawing.

The fixed mould 2 of Fig. 1 and Fig. 2 explanation and move moulds and 3 be the matched moulds state.Fixing in the fixed form (template) of for example unshowned in the drawings mold closing mechanism of fixed mould 2 (clapper die spotting press), fixing in the fixedly backing plate of the unshowned mold closing mechanism in the drawings of moving moulds.For example, push mobile backing plate to fixing backing plate with predetermined power by トダ Le mechanism etc., with the

fixed mould

2 and 3 matched moulds that move moulds.

If make up fixed mould 2 and move moulds 3, then just stipulated die cavity C, this die cavity C makes the die casting goods by filling motlten metal.

Fixed mould 2 comprises internal fixation mould 2a and surrounds the external stability mould 2b of internal fixation mould 2a, described

internal fixation mould

2a and 3 the inside of the moving moulds 3a combination regulation die cavity C that moves moulds stipulates fixed mould stream 2c in the gap (gap) in the corner on the composition surface of internal fixation mould 2a and external stability mould 2b.Fixed mould 23 is connected with moving moulds along periphery, and the cross section has the divisional plane 2f of ring-type.In addition, with contacted relative side of external stability mould 2b of internal fixation mould 2a on, have die cavity face 2d and the valve mobile space face 2e of regulation die cavity C, face 2e regulation in this space is allowed the valve mobile space Sp that the valve body 62 of stop valve 60 moves.

Observe fixed mould 2 from direction A, the cross section for example is almost circle, and fixed mould stream 2c is by shown in the illustrated in dashed lines, and the corner portions located of internal fixation mould 2a and external stability mould 2b becomes ring-type.

On fixed mould 2, the fixing shot sleeve 16 that is communicated with die cavity C.Between fixed mould 2 and the shot sleeve 16 with respect to outside seal.

Move moulds and 3 comprise outside that inside moves moulds 3a and surrounds the inner 3a that the moves moulds 3b that moves moulds, the move moulds internal fixation mould 2a of 3a and fixed mould 2 of described inside makes up regulation die cavity C, the regulation stream 3c that moves moulds in inside moves moulds the gap in corner on composition surface of 3a and the outside 3b that moves moulds.Moving moulds 3 contacts with fixed mould 2 along periphery, and relative with the die cavity face 2d of fixed mould 2, the cross section has the divisional plane 3f of ring-type.

Move moulds and 3 observe from direction A, its cross section for example is almost circle, and the stream 3c that moves moulds is by shown in the illustrated in dashed lines, be positioned at inside move moulds 3a and the outside 3b that moves moulds corner portions located and become ring-type.

Form the die cavity C that (regulation) is used to the product of casting between the die cavity face 2d of the internal fixation mould 2a of fixed

mould

2 and 3 the divisional plane 3f of moving moulds.

Between the peripheral annular part of the divisional plane 2f of the ring-type of the periphery of fixed mould 2 and relative with this divisional plane 2f 3 the divisional plane 3f of moving moulds, promptly, on the composition surface of the divisional plane of external stability mould 2b and the outside 3b that moves moulds, be provided with containment member SL, described containment member SL will be sealed into airtight conditions so that extraneous air does not invade among the die cavity C between these divisional planes 2f and the divisional plane 3f.

Containment member SL is for example formed by silicon rubber, is viewed as the O type ring of ring-type from direction A.

Stop valve 60 is set on 3 moving moulds.

Stop valve 60 comprises: the control signal 30SC that is used to self-controller 30 carry out the electromagnetic brake 61 of control action, with adjacent valve body 62, valve shaft 63 and the valve seat member 64 of valve mobile space face 2e of the internal fixation mould 2a of fixed mould 2.

Valve seat member 64 is the cylindrical structural member that comprises the second through hole 64b that makes the first through hole 64a that valve shaft 63 embeds and valve shaft 63 can be moved with the matched in clearance state, and buries move moulds 3a and outside, 3 the inside of moving moulds and move moulds among the 3b.

Valve seat member

64 and 3 the outside of moving moulds move moulds between the 3b with the direction of direction of principal axis quadrature on for example O ring of silicon rubber system of the second containment member SL2 is set.

The valve seat 64f of valve seat member 64 with 3 the divisional plane 3f consistent location of moving moulds on dispose.

Move moulds 3 and valve seat member 64 on form the exhaust pathway 52 be communicated with the second through hole 64b of valve seat member 64.Exhaust pathway 52 is connected with blast pipe 51, and blast pipe 51 is connected with main relief groove TA by the first open and close valve MV corresponding to the control signal 30SA control that comes self-controller 30.

Valve shaft 63 is embedded among the first through hole 64a of valve seat member 64, and moves to straight moving direction L shown in Figure 2 according to the electromagnetic brake 61 that moves corresponding to the control signal 30SC that comes self-controller 30.

The valve mobile space face 2e of the internal fixation mould 2a of fixed

mould

2 and 3 the outside of moving moulds move moulds between the divisional plane 3f of 3b, the valve mobile space Sp that formation can make the valve body 62 of the leading section that is arranged on valve shaft 63 move.

Valve mobile space Sp is communicated with die cavity C.Die cavity C at valve body 62 when valve seat member 64 leaves, second through hole 64b by valve mobile space Sp, valve seat member 64 and exhaust pathway 52 and be communicated with blast pipe 51.

The valve body 62 that is provided with at the leading section of valve shaft 63, by in valve mobile space Sp internally the valve mobile space face 2e of fixed mould 2a contact with the valve seat 64f of valve seat member 64 and the second through hole 64b sealed to valve seat member 64 side shiftings.Close the exhaust pathway that connects die cavity C, exhaust pathway 52 and blast pipe 51 thus.Otherwise, the valve mobile space face 2e side shifting that the valve body 62 that contacts with the valve seat 64f of valve seat member 64 passes through to the internal fixation mould 2a of fixed mould 2, the open exhaust pathway that connects die cavity C and blast pipe 51.

The electromagnetic brake that moves (opening and closing operations) 61 that carries out above-mentioned valve body 62 receives the control instruction 30SC of self-controller 30 and is driven.

A plurality of push rods 65 connect inside 3a and the outside 3b that moves moulds that moves moulds, and are arranged to 3 to move with respect to moving moulds.

In the final operation of die casting device 1 operation,, can take out die casting goods by die cavity C casting by push rod 65 is pushed to die cavity C.Push rod 65 embeds in the through hole that forms in 3 that moves moulds, push rod 65 and move moulds and be sealed into airtight conditions between 3 so that can not invade among the die cavity C from its outside extraneous air.

Shown in Fig. 1, Fig. 2 diagram, be the shift position and the translational speed of test column stopper rod 14, that is, shift position and translational speed for test column chock plug 15 are provided with position-detection sensor 35.Thus, for example at the periphery of plunger rod 14, along axially forming magnetic pole with a determining deviation.Position-detection sensor 35 for example detects the pole change of mobile plunger rod 14, converts this pole change to pulse signal output.Position-detection sensor 35 is exported detection signal 35s to controller 30.

The detection signal 35s of controller 30 position-based detecting sensors 35 calculates translational speed from the position of injection piston 17 (or the stopper head 15 in the shot sleeve 16) and the time variation (time diffusion) of position.

Controller 30 reads from position-detection sensor 35, can discern for example injection position under the low speed, second speed following injection position at a high speed for example of first speed described later, perhaps can discern the low speed injection zero hour or the high speed injection moment.

Main relief groove TA is connected with blast pipe 51 by the first open and close valve MV.Main relief groove TA is communicated with blast pipe 51, exhaust pathway 52, the second through hole 64b and valve mobile space Sp, be included in move moulds 3 and fixed mould 2 between decompression exhaust in the enclosure space of the die cavity C that forms.

The first open and close valve MV is according to coming the control instruction 30SA of self-controller 30 to open and close.

Main relief groove TA is connected with vavuum pump 50A, is decompressed to predetermined pressure by vavuum pump 50A in the main relief groove TA.If for example start vavuum pump 50A by controller 30, then vavuum pump 50A is interior in order to be maintained in predetermined vacuum state with main relief groove TA, for example carries out opening and closing operations automatically.Be decompressed to predetermined pressure (being almost vacuum state) by vavuum pump 50A before the action of the inherent following die casting device 1 of main relief groove TA.

Oxygen feedway 80 is connected with access path 53 between blast pipe 51 and the main relief groove TA by the second open and close valve GV.

The second open and close valve GV is according to coming the control instruction 30SD of self-controller 30 to open and close.If under the first open and close valve MV closing state, open the second open and close valve GV, then will be from the oxygen O of oxygen feedway 80 ₂Supply among the die cavity C by blast pipe 51, exhaust pathway 52, the second through hole 64b and valve mobile space Sp.

Space in valve mobile space Sp, die cavity C and the shot sleeve 16 is interconnected, and these constitute enclosure space.

Move moulds the composition surface of 3b divisional plane 3f in the divisional plane 2f of the external stability mould 2b of fixed

mould

2 and 3 the outside of moving moulds by the extraneous air sealing of containment member SL with respect to the outside.When stopper head 15 is crossed supply port 16h, by the inside of shot sleeve 16 is moved to the left with the supply port 16h obturation of sleeve 16, and under with stop valve 60 closing state, the enclosure space that will be made of the inside of valve mobile space Sp, die cavity C and sleeve 16 is from outside seal.

Yet, between divisional plane 2f, the 3f, valve seat member 64 and move moulds between 3, push rod 65 and move moulds between 3, be difficult to seal fully with respect to extraneous air between stopper head 15 and the sleeve 16 etc., extraneous air by these sealing positions, invade the enclosure space that the inside by valve mobile space Sp, die cavity C and sleeve 16 constitutes, can hinder to make this enclosure space become high vacuum.

In addition, extraneous air can be from the gap (gap) between internal fixation mould 2a the fixed mould 2 and the external stability mould 2b, and between move moulds internal fixation mould 3a in 3 and the gap between the external stability mould 3b, divisional plane 2f, the 3f, valve seat member 64 and move moulds between 3, push rod 65 and moving moulds invades between 3.That is, these parts become the intrusion path that enclosure space that extraneous air constitutes to the inner space by valve mobile space Sp, die cavity C and sleeve 16 is invaded.Become the intrusion path of extraneous air between stopper head 15 and the sleeve 16 too.

In addition, in these intrusion paths, be easy to unwanted gas in the suction castings such as residual air and steam.

For this reason, in the present embodiment, in fixed mould 2, form the fixed mould stream 2c that is formed by gap very little between internal fixation mould 2a and the external stability mould 2b, fixed mould stream 2c is connected with the first auxiliary exhaust pipe 90, can carry out exhaust.

Similarly, moving moulds in 3, forming by inside move moulds 3a and the outside stream 3c that moves moulds that very little gap forms between the 3b that moves moulds, the stream 3c that moves moulds also is connected with the second auxiliary exhaust pipe 91, can carry out exhaust.

Auxiliary exhaust pipe 90 is connected with assisted decompression groove TB by the 3rd open and close valve SV with 91.

The 3rd open and close valve SV opens and closes corresponding to the control signal 30SB of controller 30.

The outer peripheral face of the die cavity C side of the stopper head 15 that the inner peripheral surface of shot sleeve 16 is chimeric almost arrives a greater part of formation groove 15h.This groove 15h is communicated with inner cave from a greater part of outer peripheral face of stopper head 15, this cave further with plunger rod 14 in the pipeline connections that form, this pipeline passes through the 3rd open and close valve SV and is connected with assisted decompression groove TB.

The periphery of groove 15h by stopper head 15 is chimeric with the interior week of sleeve 16, forms the auxiliary exhaust stream of the interior gas of the inner space, die cavity C and the valve mobile space Sp that invade sleeve 16.

The also exhaust of reducing pressure of the stream that internal fixation mould 2a and fixed mould stream 2c external stability mould 2b between of assisted decompression groove TB by fixed

mould

2,3 the inside of moving moulds move moulds and forms between the inner peripheral surface of 3a and outside move moulds the groove 15h that moves moulds stream 3c and form in stopper head 15 and plunger rod 14 and sleeve 16 between the 3b, the gas of the enclosure space that inner space, die cavity C and the valve mobile space Sp of shot sleeve 16 constituted.

The 3rd open and close valve SV opens and closes by the control signal 30SB that comes self-controller 30.

Assisted decompression groove TB is connected with vavuum pump 50B, is decompressed to predetermined pressure by vavuum pump 50B in the assisted decompression groove TB.If for example,, for example carry out opening and closing operations automatically then for to make vavuum pump 50B for example preferably be almost vacuum state with being maintained in predetermined decompression state in the assisted decompression groove TB by controller 30 operated vacuum pumps 50B.Therefore, before the operation of die casting device 1, predetermined pressure (being almost vacuum state) will be decompressed in the assisted decompression groove TB by vavuum pump 50B.

Preferably, be provided with first in the access path 53 between the blast pipe 51 and the first open and close valve MV and open valve OV1, on the pipeline between first, second

auxiliary exhaust pipe

90,91 and the 3rd open and close valve SV, be provided with second and open valve OV2.These are opened valve OV1, OV2 and are used to make the open and close valve that becomes atmospheric pressure state in the mould, when common operation for closing.Behind the end-of-fill of die cavity C, make these first open valve OV1, second to open valve OV2 be open state at metallic solution, become atmospheric pressure state in the mould, just become easily so open the mould that draught head diminishes.

And, for further improving the first above-mentioned effect of opening valve OV1, wish first open valve OV1 open in, stop valve 60 is also open.

First opens the above-mentioned control operation that valve OV1, second leaves valve OV2 and stop valve 60 preferably can be undertaken by controller 30.

Below, record and narrate the corresponding relation of above-mentioned inscape and term of the present invention.

Fixed mould 2 moves moulds 3 corresponding to second mould of the present invention corresponding to first mould of the present invention.The oxygen feedway 80 and the second open and close valve GV are corresponding to oxygen feedway of the present invention.

Main relief groove TA is equivalent to first relief groove of the present invention, and the main relief groove TA and the first open and close valve MV are corresponding to first decompressor of the present invention.

At the stop valve 60 installed in 3 of moving moulds corresponding to the first open and close valve device of the present invention.

Shot sleeve 16 with supply port 16h is corresponding to shot sleeve of the present invention.

The injection piston 17 that is made of plunger rod 14 and stopper head 15 is corresponding to injection piston device of the present invention.

Oil hydraulic cylinder 11, piston rod 12 are corresponding to injection cylinder device of the present invention.

Assisted decompression groove TB is equivalent to second relief groove of the present invention, and the pipeline in the 3rd open and close valve SV, blast pipe 90, blast pipe 91, groove 15h and the plunger rod 14 etc. are corresponding to second decompressor of the present invention.

Controller 30 is corresponding to control device of the present invention.

The method of operating of die casting device, reduced pressure casting method

With reference to Fig. 3～Figure 12, the method for operating and the reduced pressure casting method of die casting device 1 is described.

Fig. 3 is that the operation format of die casting device 1 is the flow chart according to the time series explanation.

Fig. 4～Figure 12 is the figure of mode of operation of major part of the die casting device 1 of explanation each operation illustrated in fig. 3.

Operation in the following die casting device 1 is equivalent to the part of the reduced pressure casting method of embodiments of the present invention.

In the present embodiment, the following major control operation that can control automatically of die casting device 1 is undertaken by controller 30.

Fig. 3 illustrates the assisted decompression groove TB and the 3rd open and close valve SV mode of operation of the mode of operation of the mode of operation of the main relief groove TA of mode of operation of mode of operation, the main depressurized system of expression of the oxygen feedway 80 of mode of operation of mode of operation, expression oxygen feed system of whole operations, the stop valve 60 of die casting device 1 and the second open and close valve GV and the first open and close valve MV and expression assisted decompression system according to time series.

In addition, during t0 among Fig. 3～t16 constantly,, in fact be not limited to uniformly-spaced uniformly-spaced to illustrate for ease of explanation.Equally, the length of time interval T1～T4 also is not limited to the engineer's scale that illustrates.

During t0, A-stage, Fig. 2

A-stage when Fig. 2 represents the t0 of die casting device 1.

In the A-stage when t0, controller 30 is in and stops.In the A-stage of this die casting device 1, the first open and close valve MV, the second open and close valve GV, the 3rd open and close valve SV are respectively " closing " state.First opens valve OV1, second opens valve OV2 also for closing state.First,

second vavuum pump

50A, 50B also are in and stop.

In this A-stage, supply with oxygen to die cavity C from oxygen feedway 80, do not carry out decompression operation in the die cavity C by main relief groove TA, do not carry out decompression operation in the die cavity C by assisted decompression groove TB yet.In this A-stage, the inner space of shot sleeve 16 and the die cavity C that is communicated with shot sleeve 16 are exposed in the extraneous air (atmosphere).

Stop valve 60 also is in off-position (de-energise).That is, the valve body 62 of stop valve 60 is seated on the valve seat member 64, and stop valve 60 is in closes.

Stopper head 15 is positioned at the right side of the supply port 16h of shot sleeve 16, and supply port 16h is in opening.

The t1 moment: matched moulds operation (Fig. 3, S1-1), Fig. 2

At t1 constantly, for example by using not shown mold closing mechanism to carry out fixed mould shown in Figure 22 and 3 the matched moulds of moving moulds.Thus, fill the die cavity C of metallic solution ML in fixed mould 2 and the regulation between 3 of moving moulds.

Because the supply port 16h of sleeve 16 is in opening, therefore be the state that can carry out the cast of metallic solution ML from supply port 16h.

The t2 moment: the preparation of main depressurized system and assisted decompression system

At t2 constantly, controller 30 makes first vavuum pump 50A operation.Thus, the first vavuum pump 50A makes the state (being almost vacuum state) that becomes in the main relief groove TA of main depressurized system near vacuum state.Certainly, be preferably vacuum state.

Afterwards, till utilizing controller 30 to stop this operation, be predetermined vacuum state in the main relief groove TA for keeping, the preferred first vavuum pump 50A carries out automatic opening and closing operations.Similarly, at t2 constantly, controller 30 makes second vavuum pump 50B operation.Thus, the second vavuum pump 50B makes the state that becomes in the assisted decompression groove TB of assisted decompression system near vacuum state.Afterwards, till utilizing controller 30 to stop this operation, be predetermined vacuum state in the assisted decompression groove TB for keeping, the preferred second vavuum pump 50B carries out automatic opening and closing operations.

Proceed the operation of the first vavuum pump 50A till before t3 pours into a mould beginning constantly.Similarly, proceed the operation of the second vavuum pump 50B till before t3 pours into a mould beginning constantly.Thus, make main relief groove TA be in very state constantly near vacuum state at the t2 moment～t3.Similarly, make assisted decompression groove TB be in very state constantly near vacuum state at the t2 moment～t3.

At t2 constantly, the first open and close valve MV and the second open and close valve GV are in the state of closing, and the decompression operation of die cavity does not also carry out.

Therefore, 30 of controllers make the first vavuum pump 50A and second vavuum pump 50B work during necessity that decompression operation is prepared.

Except that carrying out the startup of the first vavuum pump 50A and the second vavuum pump 50B according to above-mentioned controller 30 and stopping, can also manually carrying out according to the operator of die casting device 1.In the present embodiment, explanation can controller 30 situations when driving the first vavuum pump 50A and the second vavuum pump 50B.

The t3 moment: begin cast (S1-2), Fig. 4

At t3 constantly, begin supply port 16h casting metal solution in shot sleeve 16 from shot sleeve.

The t4 moment: beginning oxygen is supplied with (S1-2), Fig. 4

At t4 constantly, controller 30 detects from supply port 16h when the inside of shot sleeve 16 begins the pouring practice of metallic solution ML, and stop valve 60 energisings of closing state are exported to electromagnetic brake 61 for the control signal 30SC that opens state.In addition, controller 30 will close the second open and close valve GV energising of state for opening the control signal 30SD output of state.

Thus, shown in Fig. 4 explanation, the valve body 62 in the stop valve 60 moves in valve mobile space Sp from the bearing state of valve seat member 64, and stop valve 60 becomes out state.Its result, the second through hole 64b and valve mobile space Sp become connected state.Therefore, lead to the second through hole 64b through the second open and close valve GV and exhaust pathway 52, oxygen is filled into the inner space of valve mobile space Sp, die cavity C and shot sleeve 16 from oxygen feedway 80.

By fill oxygen in die cavity C and shot sleeve 16, the surface oxidation of the metallic solution ML that will pour into a mould in shot sleeve 16 begins to carry out the replacement of oxygen die casting.That is the oxygen O that supplies with to die cavity C from oxygen feedway 80, ₂, lead to the inner space of shot sleeve 16 by die cavity C, emit to the outside of shot sleeve 16 from supply port 16h.

In this state, by oxygen O ₂When being full of the enclosure space that the inner space by valve mobile space Sp, die cavity C and shot sleeve 16 constitutes, by the oxygen of emitting, will in valve mobile space Sp, die cavity C and shot sleeve 16, invade the die casting that becomes of the extraneous air gas etc. of (residual) and handle the gas of harm and discharge to the outside of shot sleeve 16 from supply port 16h.Thus, oxygen remains in die cavity C etc., also gives the gas cleaning of the harmful influences such as quality of die casting goods.

For example, near the detection signal of the temperature sensor that sets the supply port 16h with not shown shot sleeve 16 is to controller 30 inputs, and the rapid variation that controller 30 detects the detection signal of temperature sensor can detect beginning casting metal solution ML in shot sleeve 16.Perhaps, according to the indication from die casting device 1 operator, controller 30 can detect the injection of knowing metallic solution ML.

And the oxygen O from oxygen feedway 80 is supplied with in beginning in die cavity C and shot sleeve 16 ₂Can begin in preceding or the cast or any situation after the cast beginning in the cast of metallic solution ML to shot sleeve 16 inner spaces.

The t5 moment: cast finishes (S1-3), Fig. 4

At t5 constantly, in order to make die casting goods, when the metallic solution ML of cast institute necessary amount in shot sleeve 16, just finish pouring practice.

Begin to stipulate according to the amount of the metallic solution ML of cast in shot sleeve 16 from cast to the time T 1 that cast finishes, rather than certain.

Owing to finish this cast, near the inside of the shot sleeve 16 the supply port 16h part of shot sleeve 16 is almost blocked by metallic solution ML.But even at this state, the second open and close valve GV is for opening state, and still continues to handle from the filling of the oxygen of oxygen feedway 80.

The t6 moment: the injection of beginning low speed (S1-4), Fig. 5

At t6 constantly, when detecting the pouring practice end, controller 30 drives oil hydraulic cylinders 11 and makes piston rod 12 driven at low speed.Its result, shown in Fig. 5 explanation, the stopper head 15 of the front end connection of the plunger rod 14 that is connected by connector 13 with piston rod 12 shown in Figure 2 is mobile in sleeve 16 with low speed.

The detection signal S35 of position-based detecting sensor 35, controller 30 calculate the position and the translational speed that move of plunger rod 14 or stopper head 15, are used to drive above-mentioned oil hydraulic cylinder 11.Translational speed is carried out time diffusion by 30 pairs of positions of controller and is tried to achieve.

Low speed by stopper head 15 moves, and the metallic solution ML that import in the shot sleeve 16 are under pressure, make this metallic solution ML not only shot sleeve 16 in vertically on, and also expansion gradually on cross-wise direction.

At this moment, the 3rd opens and closes SV for opening state, continues to fill oxygen from oxygen feedway 80 to die cavity C.

The t7 moment: oxygen is supplied with and is stopped (S2-2), Fig. 6

At t7 constantly, after t6 plunger rod 14 (or stopper head 15) the beginning low speed injection constantly through (during the t6 moment～t7 moment) after the scheduled time, when metallic solution ML becomes full state in shot sleeve 16, controller 30 outputs become the second open and close valve GV outage control signal 30SD of the state of closing, and make the second open and close valve GV stop to fill oxygen from oxygen feedway 80 to die cavity C for closing state.Thus, finish to handle by the filling of the oxygen of oxygen feedway 80 in die cavity C and shot sleeve 16.

This outer controller 30 makes stop valve 60 for closing state stop valve 60 outages, that is, valve body 62 is by contacting with valve seat member 64, and the gap that makes valve body 62 and valve seat member 64 is a closed state.

Owing to prevent the oxidation of the metallic solution ML of cast in the shot sleeve 16, and for the temperature that prevents metallic solution ML reduces, thus be carved into when wishing from t4 constantly certain hour of t7 (during) T2 lacks as much as possible.

As the replacement of oxygen die casting, after supply port 16h begins casting metal solution ML, preferred only make replacement of oxygen making in the short time of plunger rod 14 (or stopper head 15) during die cavity C side injection advances.

The t8 moment: beamhouse operation, Fig. 6 of stopping main depressurized system and assisted decompression system

Make the second open and close valve GV for closing state by controller 30, after stopping to fill oxygen by oxygen feedway 80 in die cavity C and shot sleeve 16, at t8 constantly, controller 30 stops the first vavuum pump 50A and stops decompression operation in the main relief groove TA.Similarly, controller 30 stops the operation of the second vavuum pump 50B and stops the interior decompression operation of assisted decompression groove TB.

By above decompression beamhouse operation, make main relief groove TA and assisted decompression groove TB be in very low pressure state, preferably, be decompressed to the almost state of vacuum.

In addition, stop the first vavuum pump 50A and the second vavuum pump 50B, make the pressure state of main relief groove TA and assisted decompression groove TB reach sufficient low pressure, preferably, reach to the state of vacuum almost.This moment is former constantly arbitrarily, also can carry out shut-down operation respectively independently.

The t9 moment: the sealing of supply port 16h (S1-5), Fig. 7

At t9 constantly, controller 30 drives oil hydraulic cylinder 11 in the detection signal S35 of monitored position detecting sensor 35, stopper head 15 is crossed the supply port 16h of shot sleeve 16, making the injection of stopper head 15 (plunger rod 14) low speed, is closed state until supply port 16h.Its result, shown in Fig. 7 explanation, the metallic solution ML that is subjected to the pressure of stopper head 15 near the shot sleeve 16 the supply port 16h also enlarges to the inwall direction of shot sleeve 16, makes shot sleeve 16 become the state of obstruction.Therefore, valve mobile space Sp, die cavity C and not fill the outsides that become with respect to shot sleeve 16 by metallic solution ML and stopper head 15 in the shot sleeve 16 of metallic solution ML be sealing state.Its result does not have from supply port 16h air outside and invades.

The t10 moment: main depressurized system decompression beginning, Fig. 8

After supply port 16h sealing, at t10 constantly, controller 30 will make the first open and close valve MV be out that the control signal 30SA of state exports to the first open and close valve MV.In fact, carry out constantly at t9 supply port 16h " locked in " operation t9 constantly after, controller 30 through in fact make by metallic solution ML become the preset time T4 of closed state near the shot sleeve 16 the supply port 16h after, make the first open and close valve MV for opening state.

Controller 30 makes stop valve 60 for opening state then.Thus, valve body 62 leaves from valve seat member 64.

According to aforesaid operations, by the space between blast pipe 51, exhaust pathway 52, the second through hole 64b, valve body 62 and the valve seat member 64, vacuum state or almost the main relief groove TA of vacuum state will not fill the inner space of metallic solution ML, decompression gradually in the main depressurized system of enclosure space defined such as the die cavity C, the valve mobile space Sp that connect of inner space and exhaust pathway 52 therewith in the shot sleeve 16.By this decompression operation, the oxygen of filling in the enclosure space is also discharged gradually to the outside.

This decompression operation is called first decompression operation in this manual.At t13 constantly after the high speed injection, the t15 behind the end-of-fill is constantly constantly further to proceed to t14.

The t11 moment: the operation beginning of assisted decompression system, Fig. 9

After t9 supply port 16h sealing constantly, at t11 constantly, controller 30 makes the 3rd open and close valve SV be out the control signal 30SB of state to the 3rd open and close valve SV output.

In fact, after t9 carries out the " locked in " operation of supply port 16h constantly, controller 30 through in fact make by metallic solution ML become the preset time T3 of closed state near the shot sleeve 16 the supply port 16h after, make the 3rd open and close valve SV for opening state.

Its result, utilize the vacuum state or the assisted decompression groove TB of vacuum state almost, to reduce pressure gradually and exhaust in the fixed mould stream 2c by blast pipe 90, by blast pipe 91 decompression and the exhaust gradually in the stream 3c that will move moulds, the groove 15h by stopper head 15 and the inner tube of plunger rod 14 will decompression and exhausts gradually in the shot sleeve 16.

Promptly, much less utilize from oxygen feedway 80 and in die cavity C and shot sleeve 16, supply with (filling) oxygen and pass through blast pipe 90 residual oxygen among fixed mould stream 2c, by blast pipe 91 residual oxygen in move moulds stream 3c and groove 15h, even utilize above-mentioned oxygen blow also at blast pipe 90, fixed mould stream 2c, blast pipe 91, residual oxygen among stream 3c and the groove 15h etc. moves moulds, perhaps the extraneous air of invading in these places thereafter etc. gives the small gas of harm influence in the die casting, and TB discharges gradually to the outside by the assisted decompression groove.

Utilize assisted decompression groove TB by the gas discharging operation, make fixed mould stream 2c, do not have extraneous air among the stream 3c that moves moulds etc., and these parts are not invaded extraneous air yet.

This decompression operation is called second decompression operation in this manual.Proceeding to t16 die casting constantly goods took out till the operation t15 moment before.

In the above-mentioned example, the moment of the moment of first decompression operation that finishes by main relief groove TA and second decompression operation that finishes by assisted decompression groove TB, be identical t15 constantly.

In above-mentioned example, during the situation of in narration the decompression operation (first decompression operation) of main depressurized system (first depressurized system) being carried out earlier, carrying out behind the decompression operation (second decompression operation) of assisted decompression system (second depressurized system) (scheduled time T4＞T3), under the situation after the supply port 16h sealing, also can make scheduled time T3=T4.

Perhaps, controller 30 also can make open operation by the first open and close valve MV begin the decompression that the decompression of main depressurized system and the open operation by the 3rd open and close valve SV begin the assisted decompression system to carry out simultaneously.

With above-mentioned opposite, also can carry out the decompression that begins of assisted decompression system earlier, after carry out main depressurized system begin decompression (scheduled time T3＞T4).

The t12 moment: the part operation of main depressurized system stops, Figure 10

At t10 constantly, behind the scheduled time T5 after the operation of the main depressurized system of process begins, and, t12 before t13 high speed injection constantly constantly, controller 30 makes stop valve 60 for closing the control signal 30SC of state to electromagnetic brake 61 outputs, make stop valve 60 for closing state, promptly valve body 62 is seated on the valve seat member 64.

Its result, shown in Figure 10 explanation, stop valve 60 becomes the state of closing, and becomes between valve mobile space Sp and the exhaust pathway 52 not to be communicated with.But, because the first open and close valve MV for opening state, proceeds the decompression operation of exhaust pathway 52, the second through hole 64b by main relief groove TA.

Before t13 high speed injection constantly, stop valve 60 be in the state of closing be for can prevent by high speed injection with at a high speed and the metallic solution ML that in die cavity C, imports of high pressure conditions to introducings such as valve mobile space Sp, the second through hole 64b.On the other hand, even there is not above-mentioned worry in the operation of assisted decompression system yet, the operation of assisted decompression system is continued.

During the t10 moment～t12 moment or the t11 moment～t12 moment, main depressurized system and the parallel work-flow of assisted decompression system.

Operation by main depressurized system, oxygen in the die cavity C and extraneous air (if existence) are discharged to the outside through valve mobile space Sp, the second through hole 64b and exhaust pathway 52, on the other hand, initial stage operation by main depressurized system will be by being filled in the die cavity C from the oxygen that oxygen feedway 80 is filled to inside such as die cavity C and the effect of replacement of oxygen die casting is improved in each corner of enclosure space in the shot sleeve 16 etc.In addition, by the operation of assisted decompression system, by blast pipe 90, blast pipe 91 etc. with extraneous air from fixed mould stream 2c, discharges such as stream 3c and groove 15h move moulds.

Thus,, will in die casting device 1, give the gas that the harm influence is handled in die casting, and in the arrival part of die casting device, continue to discharge according to the parallel work-flow of main depressurized system and assisted decompression system, and, make it and can not invade from the outside.

The t13 moment: high speed injection (S1-6), Figure 11

At t13 constantly, controller 30 moves piston rod 12 by driving oil hydraulic cylinder 11 to the left with high speed in graphic state.Its result, the stopper head 15 that is connected with plunger rod 14 will move to die cavity C with high speed in the shot sleeve 16.

Its result, the metallic solution ML of cast fills in die cavity C in shot sleeve 16 hastily in shot sleeve 16.High speed by metallic solution ML is injected, and the pressure in the high speed die cavity C of die cavity C uprises constantly sharp at t13.

Stopper head 15 is so that the state that moves in the shot sleeve 16 is kept preset distance.Thus, make and maintain the high state of pressure in the die cavity C.

The metallic solution ML that fills in die cavity C is full of among the die cavity C, makes the die casting goods of expectation.

The t14 moment: end-of-fill (S1-7), Figure 11

In die cavity C,, in the t14 moment through the scheduled time, finish to fill with after the high speed injection filling metallic solution ML.

T15 is constantly: main depressurized system stops fully, assisted decompression system EO, Figure 12

Behind the end-of-fill, at t15 constantly, it is the control signal 30SA that closes state that controller 30 makes the first open and close valve MV to first open and close valve MV output.Its result, shown in explanation among Figure 12, the first open and close valve MV becomes the state of closing, and finishes to come the decompression operation of autonomous relief groove TA.

To make the 3rd open and close valve SV to the 3rd open and close valve SV output be the control signal 30SB that closes state to controller 30 in addition.Its result, shown in Figure 12 explanation, the first open and close valve MV and the 3rd open and close valve SV become the state of closing, by assisted decompression groove TB, the decompression operation in the shot sleeve 16 of the decompression operation of the decompression operation of the fixed mould stream 2c of end process blast pipe 90, the stream 3c that moves moulds of process blast pipe 91 and the groove 15h of process stopper head 15 and plunger rod 14.

From A-stage to above-mentioned t15 constantly till, first opens valve OV1 and second opens valve OV2 and is in the state of closing.

Preferably, after the process t15 scheduled time constantly, can take out behind the die casting goods in the cooling die cavity C, promptly, t15 metallic solution constantly behind the end-of-fill of die cavity C, and t16 constantly before, after finishing die casting and handling, for example, controller 30 makes first to open valve OV1 and second and open valve OV2 and be in open state.Its result becomes atmospheric pressure state in the mould, so draught head diminishes, and t16 mould opening operation constantly becomes easy.

For further improving the first above-mentioned effect of opening valve OV1, wish that when open first opens valve OV1 controller 30 is also open with stop valve 60.

The t16 moment: take out die casting goods (S1-8)

Through t15 after the scheduled time constantly, cooling and the desirable die casting goods that go out in the die cavity C are removed fixed

mould

2 and 3 the matched moulds state of moving moulds, by pushing the die casting goods that push rod 65 takes out in the die cavity C.

Embodiment according to the present invention as described hereinbefore, utilize main depressurized system to apply exhaust in the die cavity C by decompression operation, by utilizing the decompression operation of assisted decompression system, get rid of in the die cavity C, in the shot sleeve 16, give the gas of harm influence in the die casting among the valve mobile space Sp etc., can make high-quality die casting goods.

In addition,, utilize decompression replacement of oxygen die casting, can make high-quality die casting goods by supplying with suitable oxygen according to present embodiment.

In addition, present embodiment can be carried out a series of operation continuously and in short time, so temperature reduction does not significantly take place the metallic solution ML of cast in the shot sleeve 16, can make high-quality die casting goods.

According to present embodiment, has the effect aspect the life-span prolongation.

According to present embodiment, to contain be full of oxygen in the enclosure space of die cavity C after, owing to utilize assisted decompression groove TB to carry out exhaust from the stream that forms between the inner peripheral surface of the groove 15h of the fixed mould stream 2c of fixed mould 2, move moulds 3 move moulds stream 3c and stopper head 15 and sleeve 16 by decompression, so positively contain each corner in the enclosure space of die cavity C with replacement of oxygen, in addition, also positively can invade gas in the path with replacement of oxygen gas.

And after positively containing the enclosure space of die cavity C with replacement of oxygen, also utilize assisted decompression groove TB by proceeding exhaust in the above-mentioned enclosure space so that unwanted gas such as invading air not in the die cavity C.

In addition, utilize that assisted decompression groove TB and main relief groove TA both sides carry out in the die cavity C, in the sleeve, gap (gap) decompression of waiting, so when shortening the required time of decompression, oxygen residual in the die cavity C is lacked in the extreme.

When implementing die casting device of the present invention and reduced pressure casting method, be not limited to above-mentioned illustrative embodiment, can carry out various modes of texturing.

In the above-described embodiment, illustrated that main decompressor of the present invention and assisted decompression device are situations about being made of main relief groove TA and assisted decompression groove TB, also can be the structure that directly reduces pressure by vavuum pump etc. without groove.

The part that makes assisted decompression groove TB action and carry out the reduced pressure treatment of die cavity C is not limited to the groove 15h of above-mentioned fixed mould stream 2c, the stream 3c that moves moulds, stopper head 15 etc., also can be suitable for extraneous air and can invade other part among the die cavity C etc.As other such parts, for example, move moulds 3 and, for example valve seat member 64 and the outside gap that moves moulds between the 3b in the gap that moves moulds between the stop valve of installing in 3 60.

Example as the operation in the die casting device of embodiments of the present invention, the situation of high speed injection after explanation is with the injection of metallic solution ML low speed, in the die casting device of embodiments of the present invention, the translational speed of the injecting method of metallic solution ML or stopper head 15 is not limited to above-mentioned two stage translational speed, for example, can be a kind of translational speed only, the perhaps translational speed that can switch by three stages etc. or translational speed injection of metallic solution in die cavity to suit.

The above-mentioned control operation of the controller 30 of utilization in the die casting device of embodiments of the present invention, for example, the opening and closing operations switching of stop valve 60, first～the 3rd open and close valve MV, GV, SV open and close switching controls etc., the for example shift position of stopper head 15 and translational speed etc. of the whole state of the die casting device that should carry out can be carried out according to the condition of decision in advance afterwards.The condition of this decision, for example, login in advance in the memory in controller 30.Thus, controller 30 is as above-mentioned illustration, can not discern the mode of operation such as low speed injection, high speed injection of stopper head 15 or metallic solution ML, by reference position detecting sensor 35 read and/or the detected value of position-detection sensor 35 with and change, can carry out control operation same as described above.

And the stop valve 60 of the corresponding first open and close valve device of the present invention can not only be mounted in and moves moulds on 3, also can be installed on the fixed mould 2.Preferably, stop valve 60 can be installed in move moulds 3 and fixed mould 2 on.Thus, can shorten the decompression time of die cavity.

In addition, be used for identical purposes, also can make main relief groove TA and assisted decompression groove TB is a common groove.Thus, the equipment of die casting device becomes simply, can make the cheap of die casting device equipment.

In addition, replace oil hydraulic cylinder 11, can use the driving means of other hydraulic medium, for example, uses with hydraulic pressure to make piston rod 12 mobile to the left and right as the driving means of medium.

Be not limited to above-mentioned illustration, can piston rod 12 moved by motor driver.

Claims

1. A mold casting device, which is a mold casting device for manufacturing molded products by filling a metal solution in a mold cavity, characterized in that it comprises:

a first mold and a second mold defining a mold cavity filled with molten metal;

the first pressure relief device;

oxygen supply device;

Installed in the above-mentioned first mold and/or the second mold, the first on-off valve device that makes the above-mentioned first decompression device or the above-mentioned oxygen supply device and the above-mentioned mold cavity in a communicable state or a non-communicative state;

An injection sleeve communicating with the above-mentioned mold cavity and having a supply port for pouring the above-mentioned metal solution on the side opposite to the side communicating with the above-mentioned mold cavity;

an injection plunger device having a plunger head movably embedded in the inner cylinder of the injection sleeve for injecting the molten metal poured into the injection sleeve from the supply port into the cavity;

injection cylinder means to drive the injection plunger means;

There is a possibility of intrusion of outside air from the outside of the above-mentioned mold cavity and/or the above-mentioned injection sleeve. A second decompression device for decompressing at least one of the gaps among the gap, the second mold, and the first on-off valve device.

2. The mold casting device according to claim 1, wherein the first decompression device includes a first decompression tank and a first on-off valve, and the oxygen supply device includes an oxygen supply device and a second on-off valve. , the second decompression device includes a second decompression tank and a third on-off valve.

3. The die casting device according to claim 2, wherein after the molten metal is poured from the supply port into the injection sleeve, the first on-off valve device is opened so that the oxygen supply device and the The mold cavity is connected, and the above-mentioned second on-off valve is in an open state, so that oxygen is supplied from the above-mentioned oxygen supply device to the above-mentioned mold cavity and the above-mentioned injection sleeve and released from the above-mentioned supply port, so that the air in the above-mentioned mold cavity and the above-mentioned injection sleeve Fill with oxygen and expel gases other than oxygen;

After filling the above-mentioned mold cavity and the above-mentioned injection sleeve with the above-mentioned oxygen, make the above-mentioned second on-off valve in a closed state, and end the filling of the above-mentioned oxygen;

After the second on-off valve is in the closed state, the first on-off valve in the first decompression device is in the open state during the first period until the filling of the molten metal into the cavity is completed, and the The first on-off valve device uses the first decompression groove to decompress the inside of the mold cavity and the injection sleeve;

After the second on-off valve is in the closed state, the third on-off valve of the second decompression device is in the open state during the second period until the filling of the molten metal into the cavity is completed, and the second on-off valve is used to reduce pressure. The groove decompresses the gap.

4. The mold casting device according to claim 2, characterized in that, after the molten metal is poured into the injection sleeve from the supply port, the molten metal is poured into the membrane cavity through the injection plunger at the first speed after the pouring is completed. During the period until the first injection of the metal solution is performed, the first on-off valve device is opened to communicate the oxygen supply device with the cavity, and the second on-off valve is opened to allow flow from the oxygen supply device to the mold cavity. Oxygen is supplied into the mold cavity and the injection sleeve and released from the supply port, so that the mold cavity and the injection sleeve are filled with oxygen and gas other than oxygen is discharged;

After the second on-off valve is in the closed state, the first on-off valve of the first pressure reducing device is opened until the second injection of the molten metal is started by the injection plunger into the cavity at the second speed. state, the above-mentioned first on-off valve device in the open state uses the above-mentioned first decompression groove to decompress the inside of the above-mentioned mold cavity and the above-mentioned injection sleeve;

After the second on-off valve is closed, the third on-off valve of the second decompression device is on until the process of filling the molten metal into the cavity is completed, and the pressure is controlled by the second decompression tank. The above gap is decompressed.

5. Molding apparatus as claimed in claim 3 or 4, characterized in that said second speed is faster than the first speed.

6. Molding apparatus as claimed in claim 3 or 4, characterized in that said first speed and said second speed are equal.

7. The molding device according to claim 3, characterized in that the molding device further has a control device,

The control unit performs the following operations:

After the metal solution is poured from the supply port into the injection sleeve by the movement of the plunger device, the first on-off valve device is operated to fill the mold cavity and the injection sleeve with oxygen, and the oxygen Release from the above-mentioned supply port to discharge gas other than oxygen in the above-mentioned mold cavity and in the above-mentioned injection sleeve;

After the pouring of the above-mentioned metal solution is completed, the above-mentioned injection cylinder device is driven to move the above-mentioned injection plunger device at a first speed, and the metal solution poured in the above-mentioned injection sleeve is started to be injected into the above-mentioned mold cavity;

After the above-mentioned mold cavity and the above-mentioned injection sleeve are filled with the above-mentioned oxygen, the above-mentioned second on-off valve is closed to stop the filling of the above-mentioned oxygen;

After the above-mentioned second on-off valve is in the closed state, the first on-off valve in the above-mentioned first decompression device is in the open state during the first period until the filling of the molten metal in the above-mentioned mold cavity is completed, and by opening The above-mentioned first on-off valve device in the above-mentioned state uses the above-mentioned first decompression groove to decompress the inside of the above-mentioned mold cavity and the above-mentioned injection sleeve;

After the second on-off valve is in the closed state, the third on-off valve of the second decompression device is in the open state during the second period until the filling of the molten metal into the cavity is completed. The second decompression groove decompresses the above-mentioned at least one gap.

8. The molding device according to claim 5, characterized in that the molding device further has a control device,

The control unit performs the following operations:

9. The molding device according to claim 6, characterized in that the molding device further has a control device,

The control unit performs the following operations:

10. The molding device according to claim 3, characterized in that the molding device further has a control device,

The control unit performs the following operations:

During the period when the pouring is completed and the first injection of the molten metal is performed by the plunger device into the mold cavity at the first speed, the first on-off valve device is opened, and the oxygen supply device and the mold cavity are connected to each other. Cavities are communicated, the above-mentioned second on-off valve is opened, and oxygen is supplied from the above-mentioned oxygen supply device to the above-mentioned mold cavity and the above-mentioned injection sleeve and released from the above-mentioned supply port, so that the inside of the above-mentioned mold cavity and the above-mentioned injection sleeve Fill with oxygen and expel gases other than oxygen;

After the second on-off valve is in the closed state, the first on-off valve in the first depressurizing device is set to In the open state, the above-mentioned first on-off valve device in the open state uses the above-mentioned first decompression groove to decompress the inside of the above-mentioned mold cavity and the above-mentioned injection sleeve;

After the second on-off valve is in the closed state, until the process of filling the molten metal into the cavity is completed, the third on-off valve of the second decompression device is in the open state, and the second on-off valve is used to reduce the pressure. The groove decompresses the at least one gap.

11. The molding device according to claim 5, characterized in that the molding device further has a control device,

The control unit performs the following operations:

12. The molding device according to claim 6, characterized in that the molding device further has a control device,

The control unit performs the following operations:

13. The molding device according to claim 7 or 10, characterized in that the molding device has a position sensor for detecting the position of the injection plunger, and the control device obtains It is judged that the above-mentioned injection plunger device performs injection at the above-mentioned first speed or the above-mentioned second speed.

14. The mold casting apparatus according to claim 1, wherein said first mold is a fixed mold comprising: an inner fixed mold, an outer fixed mold surrounding the inner fixed mold, and said inner fixed mold is connected to said inner fixed mold. The fixed mold flow path formed by the gap between the external fixed molds; the above-mentioned second mold is a movable mold, including: an internal movable mold, an external movable mold surrounding the internal movable mold, and between the above-mentioned internal movable mold and the above-mentioned external movable mold The moving mold flow path formed by the gap, the second decompression device is operatively connected to the fixed mold flow path and the moving mold flow path.

15. A reduced-pressure casting method for a die-casting device, the method being used for a die-casting device for manufacturing die-cast products by an oxygen displacement die-casting method, characterized in that it comprises the following steps: from a supply port to an injection sleeve After starting the pouring of the molten metal, filling the mold cavity and the injection sleeve with oxygen until the pouring is completed and the injection plunger is moved at a first speed to inject the molten metal into a prescribed cavity in the mould, and Oxygen purging process for filling the mold cavity and the injection sleeve with oxygen and discharging gas other than oxygen from the supply port;

After the filling of the oxygen gas is completed, before the injection plunger is moved at the second speed to start injecting the molten metal into the cavity, the first decompression is to decompress the inside of the cavity and the injection sleeve. process;

The second depressurization method is to decompress the part of the mold cavity and/or the sleeve in the mold casting device that can enter the outside air from the outside after the filling of the oxygen gas is completed and before the molded product is taken out. Pressing process.

16. The reduced-pressure casting method according to claim 15, characterized in that, in the oxygen purging process, the valves provided between the mold cavity and the oxygen supply device and between the mold cavity and the first pressure reducing device The first on-off valve device is in an open state, so that the above-mentioned oxygen supply device and the above-mentioned mold cavity are in a communicable state, and the second on-off valve device provided between the above-mentioned first on-off valve device and the above-mentioned oxygen supply device is in an open state. Oxygen is supplied from the above-mentioned oxygen supply device to the above-mentioned mold cavity and the above-mentioned injection sleeve through the above-mentioned first on-off valve device and released from the above-mentioned supply port, so that the above-mentioned mold cavity and the above-mentioned injection sleeve are filled with oxygen and discharged. For gases other than gas, after filling the above-mentioned mold cavity and the above-mentioned injection sleeve with the above-mentioned oxygen, make the above-mentioned second on-off valve device in a closed state, and end the filling of the above-mentioned oxygen;

In the first depressurizing step, after the second on-off valve device is in the closed state and until the filling of the molten metal into the cavity is completed, the gap between the first depressurizing device and the cavity is The above-mentioned first on-off valve device provided between is in an open state, and the above-mentioned first on-off valve in the open state uses the above-mentioned first decompression device to depressurize the inside of the above-mentioned mold cavity and the above-mentioned injection sleeve;

In the second decompression step, after the second on-off valve device is in the closed state and until the filling of the molten metal into the cavity is completed, the second decompression device and the intrusive external The third on-off valve device provided between the air parts is in an open state, and the part where outside air can enter from the outside is decompressed by the second decompression device.

17. The reduced-pressure casting method according to claim 15, characterized in that, in the oxygen purging step, the valves provided between the mold cavity and the oxygen supply device and between the mold cavity and the first pressure reducing device The first on-off valve device is in an open state, so that the above-mentioned oxygen supply device and the above-mentioned mold cavity are in a communicable state; the second on-off valve device provided between the above-mentioned first on-off valve device and the above-mentioned oxygen supply device is in an open state Oxygen is supplied from the above-mentioned oxygen supply device to the above-mentioned mold cavity and the above-mentioned injection sleeve through the above-mentioned first on-off valve device and released from the above-mentioned supply port, so that the above-mentioned mold cavity and the above-mentioned injection sleeve are filled with oxygen and discharged. For gases other than gas, after filling the above-mentioned mold cavity and the above-mentioned injection sleeve with the above-mentioned oxygen, make the above-mentioned second on-off valve device in a closed state, and end the filling of the above-mentioned oxygen;

In the first decompression step, after the second on-off valve device is in the closed state, until the second injection of the metal solution into the mold cavity is started by the injection plunger at the second speed, the first The first on-off valve device provided between the decompression device and the above-mentioned mold cavity is in an open state, and the first on-off valve in the open state utilizes the above-mentioned first decompression device to carry out the injection in the above-mentioned mold cavity and the above-mentioned injection sleeve. stress reliever;

In the second decompression step, after the second on-off valve device is in the closed state and until the filling of the molten metal into the cavity is completed, the second decompression device and the intrusable outside air The third on-off valve device provided between the parts is in an open state, and the part that can invade the outside air from the above-mentioned outside is decompressed by the above-mentioned second decompression device.