EP2506999B1 - Injection unit for a die-casting machine - Google Patents

Description

The invention relates to a casting unit for a die casting machine according to the preamble of claim 1.

Casting units are typically used in the corresponding die casting machines, e.g. hot chamber or cold chamber type, to promote a molten metal by the action of the casting piston from the casting chamber at high speed and high pressure in a mold cavity. In the mold cavity, solidification of the molten metal then forms the desired metallic casting. Depending on the casting material, e.g. Alloys of zinc, Al or magnesium, and casting to be produced, the casting unit has relatively high temperatures and pressures of the molten metal of e.g. to withstand over 600 ° C and 1000 bar, which is known to require special design measures.

In conventional casting units, the casting piston is typically designed as a slide piston which can be axially moved back and forth in a hollow-cylindrical casting chamber body, its outer cross-section corresponding to the internal cross-section of the casting chamber body. In other words, this spool forms a casting chamber volume variably delimiting, axially movable end wall of the casting chamber, this conventional Gießkolbentyp by its the inner cross section of Gießkammerkörpers corresponding outer cross section seals the Gießkammervolumen to this end side, possibly supported by associated sealing means, which are arranged for example on the piston outer periphery , The power transmission to the casting piston via a provided on the casting chamber facing away from the front end of the casting piston piston shaft with respect to the casting piston of smaller cross-section. The Gießkolbenschaft, for example, by an associated passage opening in Gießkammerkörper from the latter be led out, in which case this passage opening has a corresponding to that of the piston skirt cross section, which is smaller than the casting piston outer cross section and the inner cross section of the cylindrical casting chamber body.

Various conventional casting units of this type are disclosed, for example, in the published patent applications DE 10 2005 009 669 A1 . DE 195 44 716 A1 and DE 43 16 927 A1 as well as in the patent EP 1 483 074 B1 disclosed.

Casting units with said spool type pose some specific technological challenges. One problem is the effect of so-called edge shell solidification. As a result of the comparatively cooler cylinder wall of the casting chamber body, melt material can solidify on its inner wall and disturb or aggravate the movement of the casting piston sealingly moving along it with two-dimensional surface contact. In addition, when casting piston moved back except for casting material usually also air in the casting chamber, which in the mold filling, i. when advancing the casting piston, must be expelled again or can lead to melt oxidation problems.

In contrast, casting units of the displacer type according to the preamble of claim 1 have already been proposed. The publication EP 0 576 406 A2 discloses such a casting unit, wherein there the casting chamber is cylindrical with a substantially constant diameter along its length and the casting piston is designed as a vorbewegbare cylindrical rod with an annular stepped widened foot part, the piston diameter both in the bar area and in the widened foot area smaller than the inner diameter of the cylindrical casting chamber is. A piston entrance side portion of the casting chamber body forms a cylindrical passage opening with respect to the inner diameter the casting chamber larger opening diameter, a ring-cylindrical seal pack is firmly clamped in this passage opening is taken by pressing against the front by an end face screwed to the casting chamber body pressure plate against an axially opposite annular shoulder, where the wider passage opening merges into the narrower casting chamber. The axially preloaded sealing pack is supported radially outwardly on the inner wall of the passage opening of the casting chamber body. The widened foot part of the casting piston is required to be able to remove the sealing packing stuck in the lead-through opening if necessary.

Other conventional casting units with a cylindrical casting chamber, in which a displacement piston is arranged with respect to the Gießkammerdurchmesser smaller piston diameter, are in the patent US 3,814,170 and the publication DE 32 48 423 A1 disclosed.

The technical object of the invention is to provide a casting unit for a die casting machine which can overcome or at least reduce the above-mentioned difficulties of conventional sliding piston type casting units and which offers advantages over conventional positive displacement casting units.

The invention solves this problem by providing a pouring unit having the features of claim 1. In this pouring unit, the pouring piston extends through a feedthrough opening of the pouring chamber body from outside into the pouring chamber, with a free space region of the pouring chamber being moved between an outer casing surface of the pouring chamber into the pouring chamber Casting piston and one of these transverse to the casting piston longitudinal direction opposite inner wall surface of the casting chamber body is formed by an outer cross section of the casting piston is correspondingly smaller than an inner cross section of the casting chamber body.

In other words, in the casting unit according to the invention, the casting piston is of a displacer type which accordingly reduces the casting chamber volume by moving forward into the casting chamber without sealingly abutting its outer cross section in the manner of a conventional slide piston against the inner cross section of the casting chamber body. By leaving the free space area, any friction problems between the outer cross section of the casting piston and the inner cross section of the casting chamber body, which is opposite to the casting piston longitudinal direction, are eliminated. due to the mentioned edge shell solidification effect. A problem of friction due to two-dimensional, surface frictional contact can thus be limited locally to the region of the leadthrough opening. This is much easier manageable than the conventional friction problem between Gießkolbenaußenquerschnittsfläche and inner cross-sectional area of Gießkammerkörpers along the entire displacement length in the conventional slide piston type. If necessary, a one-dimensional, line-shaped or zero-dimensional, point-shaped guide contact between the casting piston and the casting chamber boundary wall can be maintained. In addition, this design of the pouring unit according to the invention comparatively easily offers the possibility of always keeping the casting chamber completely filled with casting material without necessarily causing ambient air to enter the casting chamber.

According to one aspect of the invention, a casting piston temperature control device is provided for at least partially active temperature control of the casting piston. As a result, the temperature of the casting piston can be actively influenced as required and in the case of application, the part of which is in each case located in the casting chamber the temperature is affected by the local hot casting material. In this case, the casting-piston tempering device is designed to be able to actively temper the casting piston along at least part of its length in accordance with a predeterminable temperature profile. For example, a temperature influence of the hot casting material leading to a temperature gradient along the casting piston in the casting chamber can thus be suitably partially compensated or completely compensated for on the casting piston.

According to a further aspect of the invention, a sealing element is provided for sealing the Gießkolbendurchführung. The sealing element is arranged on a casting chamber facing the inside of the passage opening or the guide sleeve. Arranging on the inside has the advantage that solidified melt material, if it should come to a solidification effect in this area, can easily be pushed back into the casting chamber during advancement of the casting piston without resulting in disturbing phenomena of friction between the casting piston and the inner wall of the casting chamber body Has. Even when moving back the casting piston makes melt material that eventually solidifies in the region of the sealing element on the inside of the lead-through opening or the guide sleeve, no problems, if only because this return movement can take place quasi unpressurized in contrast to the advance of the casting. Because the casting material in the casting chamber is not in the return movement of the casting piston under the high pressure, as it prevails during the Formfüllphase when advancing the casting piston, but is depressurized or at most under a much lower supply pressure, optionally for feeding of casting material into the casting chamber can be used.

According to a further aspect of the invention, the casting piston has an outer diameter which extends at least via one into the casting chamber into and through the passage opening through movable part of the casting piston is constant and corresponds to the diameter of the passage opening substantially. An annular gap thus remains as a free space region of the casting chamber between the casting piston section, which is moved forward into the casting chamber, and the radially opposite inner wall surface of the casting chamber body, which has a larger inner diameter than the outer diameter of the casting piston, which remains permanently in the casting chamber volume which is not closed off by the casting piston. Since the constant outer diameter of the casting plunger part in question essentially corresponds to the diameter of the lead-through opening, the casting plunger is guided safely and without play in the bushing opening itself.

In one development of the invention, the casting material inlet opens into the free space region and / or into the casting material outlet of the casting chamber. This has the advantageous consequence that the pouring chamber inlet is not blocked even with maximum advancing casting piston of the latter. Thus, casting material can already be supplied from the beginning of the return movement of the casting piston from its maximum advancing position via the pouring inlet into the casting chamber. In contrast, in conventional pouring piston-type casting units, the pouring inlet is mostly blocked by the advancing pouring piston and is released therefrom only when the pouring piston has moved back a certain distance from its maximum advancing position. The present pouring unit consequently enables a comparatively uniform, homogeneous feeding of casting material into the casting chamber and thus also the avoidance of undesirable turbulences and an undesired suction of ambient air via the casting material outlet during the backward movement of the casting piston. The casting chamber can thus always be kept completely filled with casting material without further notice.

In a further embodiment, the casting material inlet and / or a casting material supply line assigned to it are provided with a shut-off element which prevents casting material from emerging from the casting chamber via the casting material inlet. Depending on requirements and application, it may be an active or passive shut-off element of conventional type, e.g. around a corresponding check valve.

In a further development of the invention, the casting chamber body has a hollow cylinder, and the passage opening is provided at a front end thereof. The casting piston can then extend, for example, with the piston longitudinal axis parallel to the hollow cylinder longitudinal axis, axially via the passage opening into the casting chamber. In a further embodiment, the casting material outlet and / or the casting material inlet is provided on the end face of the hollow cylinder opposite the feed-through opening or on a cylinder jacket surface of the hollow cylinder. These positioning measures can contribute to a favorable flow characteristic for the pouring material to be introduced into the casting chamber and from this under pressure into a mold cavity.

In a further development of the invention, a guide sleeve is provided for the casting piston, which extends from one of the casting chamber outside of the passage opening to the outside and / or from one of the casting chamber facing inside the passage opening into the casting chamber inside. With this guide sleeve, the casting piston can be additionally supported and guided during its forward and backward movement.

In a development of the invention, a casting chamber temperature control device is provided for active temperature control of the casting chamber. This can be used, for example, melt solidification effects Prevent in the casting chamber or to achieve a relatively homogeneous temperature distribution of the casting material in the casting chamber. In a further development of the invention, the casting unit has a relief ring groove and a discharge channel, wherein the relief ring groove is located on a casting piston facing inner wall of the passage opening or the guide sleeve and the discharge channel leads from the Entlastungsringnut out to the outside of the casting chamber. If, for example, because of wear, some melt material or another fluid passes between the casting piston and the feedthrough opening or guide sleeve, this can be removed in a controlled manner via the relief ring groove and the discharge channel to the outside.

Fig. 1

in einer schematischen Seitenansicht eine Gießeinheit für eine Druckgießmaschine,

Fig. 2

eine Ansicht entsprechend Fig. 1 für eine Variante der Gießeinheit mit Entlastungsringnnut und Entlastungskanal,

Fig. 3

eine Ansicht entsprechend Fig. 2 für eine Variante der Gießeinheit, bei welcher ein Gießmaterialeinlass in einen Gießmaterialauslassbereich statt einen Freiraumbereich der Gießkammer mündet,

Fig. 4

eine Ansicht entsprechend Fig. 2 für eine Variante der Gießeinheit mit einer sich primär in die Gießkammer hinein statt von der Gießkammer nach außen erstreckenden GießkolbenFührungshülse und

Fig. 5

eine Ansicht entsprechend Fig. 4 für eine Variante der Gießeinheit ohne aktive Gießkammertemperierung.

Advantageous embodiments of the invention are illustrated in the drawings and will be described below. Hereby show:

Fig. 1

in a schematic side view of a casting unit for a die casting machine,

Fig. 2

a view accordingly Fig. 1 for a variant of the casting unit with relief ring groove and relief channel,

Fig. 3

a view accordingly Fig. 2 for a variant of the pouring unit, in which a pouring material inlet opens into a pouring material outlet region instead of a free space region of the pouring chamber,

Fig. 4

a view accordingly Fig. 2 for a variant of the casting unit with a casting piston guiding sleeve extending primarily into the casting chamber instead of from the casting chamber to the outside

Fig. 5

a view accordingly Fig. 4 for a variant of the casting unit without active casting chamber temperature control.

In the Fig. 1 schematically illustrated casting unit is particularly suitable for processing liquid and semi-molten metal melts, such as alloys of tin, zinc, lead, aluminum, magnesium, titanium, steel or copper or more of these metals, mixtures of several metals and optionally such materials with admixtures of particles, in an associated die casting machine. The casting unit can be installed, for example, as a so-called vertical or horizontal casting unit in the caster in question, depending on requirements and in particular depending on Druckgießmaschinentyp. The casting unit has a casting chamber body 1, which in the example shown comprises a hollow cylinder 1a, which forms a casting chamber 2 with its interior. At one in Fig. 1 right end face is a Gießmaterialauslass 3 is provided, can be promoted on the casting material from the casting chamber 2 in a conventional, not further shown manner in a mold cavity, which is formed in a conventional manner by a fixed and a movable mold half of the die casting machine and the contour of a produced Castings defined.

Furthermore, the casting unit comprises a casting piston 4, which is realized as an elongated displacement piston and extends through a passage opening 5 of the casting chamber body 1 from the outside into the casting chamber 2. In the example shown, the lead-through opening 5 is provided at the end face of the hollow-cylindrical casting chamber body 1 opposite the pouring material outlet 3, and in the same way as the pouring material outlet 3 centrally to a longitudinal axis 1b of the casting chamber hollow cylinder 1. The casting piston 4 is aligned with the hollow cylinder longitudinal axis 1b Longitudinal axis 4a held axially movable back and forth, as symbolized by a movement double arrow B, where he in Fig. 1 is shown in a rearward end position.

The casting piston 4 has an outer diameter d which is constant at least via a part of the casting piston 4 that can be moved into the casting chamber 2 or through the lead-through opening 5 and essentially corresponds to the diameter of the lead-through opening 5. Optionally, this part of the casting piston 4 may also have a slightly conical shape, in which case provision must be made for a suitable sealing. In contrast, the casting chamber hollow cylinder 1a has a larger inner diameter D, ie D> d, so that between the advancing into the casting chamber and the radially opposite casting chamber an annular gap 6 remains as a free space region of the casting chamber, which permanently belongs to the casting chamber, since he not shut off from the casting piston. In other words lie in one in the Fig. 1 indicated by dashed lines, advanced Gießkolbenstellung 4 'an outer circumferential surface 4b of the casting piston 4 and an inner wall surface 1c of the hollow cylindrical Gießkammerkörpers 1 with a radial clearance distance Dd, the free space annular gap 6 thus formed during operation is permanently filled with the casting material located in the casting chamber 2. It is understood that the casting piston 4 in its not in the casting chamber 2 into movable rear section a can have any cross-sectional configuration, such as a stepped or conical shape.

In the rear end piston position shown, a pouring-chamber-side front end 4c of the casting piston 4 is located at a short distance from the passage opening 5 in the casting chamber 2. From this rear end position, the casting piston 4 can each be advanced so far that the desired amount of liquid or partially liquid casting material in the associated Mold filling is discharged from the casting chamber 2 in the mold cavity, ie The volume of casting material to be discharged is equal to the volume of the casting plunger 4 moved into the casting chamber 2. The casting plunger 4 can be advanced to a position in which its front face end 4c reaches the inner wall of the casting chamber body 1 at the end face which is the Gießmaterialauslass 3, wherein the piston diameter d in this example is greater than a diameter a of the Gießmaterialauslasses 3. Alternatively, it may be provided to choose the diameter a of the Gießmaterialauslasses 3 greater than the piston diameter d. In this case, the casting piston 4 can advance with its front end 4c into the Gießmaterialauslass 3, if appropriate for the particular application. The front end position of the casting piston 4 can be defined by the stroke of a conventional, not shown drive for the casting piston 4 or by a corresponding limit stop.

Casting material can be supplied to the casting chamber 2 via a casting material supply line 7 and an associated casting material inlet 8, which is introduced into a cylinder jacket surface of the hollow cylinder 1a. This has the consequence that the casting material inlet 8 opens into the annular gap-shaped free space region 6 of the casting chamber 2 and is thereby not blocked off by the advancing casting piston 4. The casting material inlet 8 and / or the casting material supply line 7 are provided with a active or passive acting shut-off element 9 is provided with which prevents the casting material located in the casting chamber during advancement of the casting piston 4 in the casting chamber 2 can escape via the casting material inlet 8. For example, the shut-off element 9 can be realized as a check valve as shown schematically.

For sealing the passage of the casting piston 4 through the passage opening 5, a sealing element 10, e.g. a sealing rubber or metal ring, provided on a casting chamber side inside the passage opening 5. The sealing element 10 is preferably designed, e.g. As a correspondingly shaped sealing lip member that it presses under the pressure of the casting material in the casting chamber 2 sealingly against the performed casting piston 4 and / or embedded in the passage opening 5 or inserted. For the sealing element 10 is an elastic or non-elastic design with suitable geometry can be used as needed.

To guide the axially movable casting piston 4, a guide sleeve 11 is provided with the piston diameter d corresponding sleeve inner diameter, which is realized in the example shown as an axial extension or flange of the casting chamber 1. At the same time, the guide sleeve 11 in the exemplary embodiment shown serves to receive a guide sleeve tempering device 12, which serves for the active guide sleeve temperature control and, as shown, can also extend axially into the region of the leadthrough opening 5. The temperature control device 12 can also contribute to the temperature control of the guided in the guide sleeve 11 casting piston 4. It may, for example, be of a type with a liquid or gaseous tempering medium which is passed through tempering passages which surround the casting plunger 4 coaxially in the corresponding section of the guide sleeve 11 or the leadthrough opening 5.

For active Gießkolbentemperierung, as shown in the embodiment shown, a corresponding Gießkolben tempering device 14 may be provided, which in turn is for example of a type with a liquid or gaseous temperature control, which is passed through one or more temperature control channels 14a, which in the casting piston 4 itself extend. In the exemplary embodiment shown, this is realized in that a tempering tube 15 is longitudinally inserted into an interior 16 of the casting piston 4 realized for this purpose as a hollow cylinder, leaving an annular gap between the temperature control tube 15 and the casting piston inner wall. The annular gap represents a first temperature control channel, while the temperature control tube 15 represents a second temperature control channel, whereby the temperature control medium can be guided via one of the two temperature control channels into the front casting piston area and can be led back to the rear via the other temperature control channel.

The tempering devices 12, 14 mentioned can be used to actively temper the casting piston 4 or the guide sleeve 11 in the relevant section, eg according to a predeterminable temperature profile along at least part of its length which can be advanced into the casting chamber. In particular, this can be counteracted depending on the needs and application of the influence of temperature of the hot casting melt in the casting chamber 2 on the movable into the casting chamber part of the casting piston 4, for example, for the purpose of not causing excessive axial temperature gradients in the casting piston 4, due to locally different piston material expansion could complicate the sealing of the casting piston 4 at the passage opening 5. The two temperature control devices 12, 14 can be suitably matched to one another for this purpose of a desired temperature control of the casting piston 4 and expediently also of the guide sleeve 11, wherein in alternative embodiments also only one of the two tempering 12, 14 may be provided.

Furthermore, a casting chamber temperature control device 13 is provided, with which the casting chamber 2 together with casting material inlet 8 together with adjoining casting material supply line 7 and casting material outlet 3 together with adjoining casting material outlet line can be controllably actively controlled in a desired manner. For this purpose, this tempering device 13 can also be used e.g. be of a type with a liquid or gaseous tempering medium, which is passed through tempering, which coaxially surround the hollow cylinder 1a and the Gießmaterialzufuhrleitung 7 and / or the Gießmaterialauslassleitung. With this tempering device 13, it is consequently possible to keep the casting material at a comparatively constant temperature level without strong temperature gradients, when it is fed into the casting chamber 2 via the supply line 7 for the next casting operation, stored there and then discharged via the casting material outlet 3 in the mold filling process becomes. If required, the tempering device 13 can be divided into a plurality of separately controllable tempering zones or tempering units.

As already apparent from the above description of the structural conditions, in the casting unit shown, the casting piston 4 acts as a pure displacer whose feed into the casting chamber 2 determines the quantity of melt to be discharged from the casting chamber 2 at high speed and high pressure, as usual the casting piston 4 moves freely into the casting chamber 2, without having to conduct its surface along a cylindrical inner wall of the casting chamber body 1 flat. Disturbing frictional effects on a corresponding sliding surface between the casting piston and Gießkammerwand, as the conventional casting of the spool type are inherent, account for principle in this casting unit of Verdrängerkolbentyp.

In addition, it can be relatively easily avoided that when the mold piston 4 is moved back into the casting chamber 2 after the mold filling process has ended. Because the advancing casting piston 4 does not block the casting material inlet 8, so that when moving back the casting piston 4 immediately casting material can be fed via the supply line 7 and the then opening shut-9 in the casting chamber 2. This introduction of casting material takes place e.g. substantially depressurized or with a slight overpressure, and in each case the suction of air can be e.g. be avoided via the pouring material inlet 3, if desired. The desserts can also be improved by the fact that forms a closing plug at the Gießmaterialauslass by Gießmaterialerstarrung towards the end of the respective casting cycle, which prevents the ingress of air.

The displacement piston principle implemented here facilitates the construction of a high pressure and the movement of the casting piston 4 at high speed to effect the mold filling, wherein the then closed shut-9 holds the casting material 8 closed, so that the casting material displaced by the casting piston 4 alone on the Gießmaterialauslass 3 from the pouring chamber 2 out to fill the mold cavity. Furthermore, the casting piston configuration according to the invention has the advantage that no piston lubricant is needed and consequently no corresponding residues can occur in the casting produced.

The Fig. 2 to 5 illustrate various advantageous variants of the casting of Fig. 1 wherein like reference numerals are used to facilitate understanding of identical or functionally equivalent elements are and to that extent on the above remarks to casting unit of Fig. 1 can be referenced.

In the Fig. 2 shown casting unit has in addition to that of Fig. 1 a relief annular groove 17 and an associated discharge channel 18. The relief annular groove 17 is annularly introduced in this example in the inner wall of the guide sleeve 11, and at an axial height between the passage opening 5 of the casting chamber 1 and the axially outer end face of the guide sleeve 11. The discharge channel 18 leads from the relief ring groove 17 to the outside, ie in the outer space outside the casting chamber 1, to which the relief channel 18 is introduced, for example, as a radial bore through the wall of the guide sleeve 11 therethrough.

The relief annular groove 17, together with the relief channel 18, forms a leak-removing means for the controlled removal of any material, such as melt material, which may undesirably enter the gap between the casting piston 4 and the through-hole 5 or guide sleeve 11, e.g. due to wear on the outside of the casting piston 4, on the sealing element 10 and / or on the inside of the passage opening 5 and the guide sleeve 11th

In the Fig. 3 shown casting unit is different from those of Fig. 1 and 2 in that the casting material inlet 8 does not open into the free space area 6 but into the area of the casting material outlet 3 of the casting chamber 2. This placement of the casting material inlet 8 ensures that it is not blocked off by the advancing casting piston 4. Otherwise, the above apply to the embodiments of Fig. 1 and 2 explained properties and advantages in the same way for the casting unit of Fig. 3 ,

In the Fig. 4 shown casting unit is different from those of Fig. 1 and 2 in that for the supported guidance of the casting piston 4, a guide sleeve 11 'is formed which in this case extends primarily into the casting chamber 2, ie with a predeterminable axial guide sleeve length into the clearance region 6 remaining between the casting piston 4 and the casting chamber inner wall 1c. The sealing element 10 is arranged in this example in the region of the inner front end of this guide sleeve 11 'and embedded therein. The relief annular groove 17 and the relief channel 18, which may also be optionally provided in this variant of the casting unit, are located in the region of a relatively short axial part of the guide sleeve support of the casting piston 4 pointing outwards from the actual casting chamber hollow cylinder 1a.

Since in this embodiment, the majority of the guide sleeve 11 'is in the casting chamber 2 and therefore can be heated during operation of the present there melting material, the guide sleeve tempering device 12, as shown in the Fig. 1 to 3 is shown, optional omitted.

In the Fig. 5 shown pouring unit corresponds to that of Fig. 4 with the exception that in this case the tempering device 13 is not provided for active Gießkolbentemperierung. This casting unit is suitable, for example, for applications which do not require active heating of the casting chamber 2. This variant can be used, for example, for applications in which the complete casting unit dips into a melt bath, so that the casting unit is heated passively via the hot melt material, ie the hot, liquid melt material surrounds the casting chamber 2 or the casting chamber body 1 and holds them or this warm from the outside. In addition, this can be introduced via the casting material inlet 8 from the melt bath into the casting chamber 2 Melting material keep the casting chamber 2 warm from the inside, as is the case with the other embodiments shown.

It is understood that further variants of the casting unit according to the invention are possible, in which the variants of the Fig. 2 to 5 mentioned different modifications are combined in a different way. For example, in all cases the relief annular groove 17 with the discharge channel 18 is optionally present or not. In this case, the relief annular groove 17, as an alternative to the aforementioned circular design, for example, also have a helically curved course. The mouth of the casting material inlet 8 into a region of the Gießmaterialauslasses 3, as to Fig. 3 can also be seen in the variants of Fig. 4 and 5 be provided. In addition, in the variant with not actively heated casting chamber 2 according to Fig. 5 instead of the shown, primarily in the casting chamber 2 in-looking guide sleeve 11 'may be provided a primary outwardly facing guide sleeve, as the guide sleeve 11 in the variants of Fig. 1 to 3 ,

It is also understood that the invention is not limited to the embodiments shown in the figures or mentioned above. Thus, in other embodiments of the invention further modifications thereof may be provided, for example, a casting piston having a non-circular cross-section and a correspondingly designed passage opening may be used, and / or the guide sleeve may be realized as a component separately from the casting chamber body, possibly as a component mounted thereon , In further embodiments of the invention, the casting material inlet and the casting material outlet may be interchanged with respect to their positions in the embodiment shown or may open into the casting chamber at any other positions. The casting piston may, in corresponding embodiments, also transversely to the longitudinal direction of the Gießmaterialauslasses and / or the pouring material inlet into the pouring chamber. For each of the aforementioned tempering 12, 13, 14 in addition to those mentioned any other skilled in the art for this application type of construction can be used, in the case of a heater, for example, an electric heater with electric heating elements.

In the examples shown, the clearance area is formed as a circumferentially continuous annular gap, i. the casting piston moves freely in the casting chamber 2 without support. In alternative embodiments, a point or line guide of the casting piston may be provided within the casting chamber, i. In such embodiments, the casting piston engages with an outer circumferential surface along one or more line contacts and / or along one or more point contacts against a transverse to the casting piston movement direction opposite boundary wall of the casting chamber. In these cases, although there is a certain friction between the casting piston and a casting chamber boundary wall, it is characterized by having only one-dimensional line contact or zero-dimensional point contact, less than in the conventional case of spool type wherein the outer circumferential surface of the casting piston has a two-dimensional frictional contact surface over its entire surface abuts against the opposite Gießkammerwandung. Thus, the illustrated embodiment could be used in the sense of line contact e.g. be modified so that the hollow cylinder inner wall 1c or the casting piston outer circumferential surface 4b arranged distributed on the circumference, is provided with axial direction component extending guide webs, which keep the casting piston 4 guided within the casting chamber 2 in its axial movement. These guide webs then divide the annular gap clearance 6 into several corresponding segments.

Claims (8)

1. A casting unit for a diecasting machine, comprising

   - a casting chamber body (1) including a casting chamber (2) which is capable of being filled with casting material and comprises a casting material inlet (8) and a casting material outlet (3), and

   - a casting piston (4) which is capable of being moved forward in a longitudinal direction of the casting piston in the casting chamber, in order to discharge casting material from the casting chamber under pressure via the casting material outlet, and moved backward, in order to feed casting material into the casting chamber via the casting material inlet,

   - wherein the casting piston (4) extends through a through-passage (5) of the casting chamber body (1) from outside into the casting chamber (2), an area of free space (6) of the casting chamber being formed between an outer lateral surface (4b) of the casting piston moved forward into the casting chamber and an inner wall surface (1c) of the casting chamber body lying opposite said outer lateral surface transversely in relation to the longitudinal direction of the casting piston, by an outer cross section (d) of the casting piston being correspondingly smaller than an inner cross section (D) of the casting chamber body,

   characterized in that

   - a casting piston temperature control device (14) for actively controlling the temperature of the casting piston, at least in certain regions, is provided and designed for allowing the temperature of the casting piston to be actively controlled according to a predeterminable temperature profile along at least part of its length that can be moved forward into the casting chamber, and/or

   - a sealing element (10) for sealing off the casting piston passage is provided at an inner side of the through-passage (5) so that it presses sealingly against the passing casting piston (4) by the pressure of the casting material in the casting chamber (2), where an outer diameter (d) of the casting piston (4) substantially equals a diameter of the through-passage (5), and/or

   - the casting piston (4) has an outer diameter (d) which at least over a part of the casting piston (4) that can be moved into the casting chamber (2) and through the through-passage (5) is constant and substantially equals the diameter of the through-passage (5), where an annular gap remains as the area of free space of the casting chamber (2) between the casting piston portion moved forward into the casting chamber (2) and the radially opposed inner wall surface (1c) of the casting chamber body which has an inner diameter (D) greater than the outer diameter (d) of the casting piston (4), said annular gap permanently belonging to the casting chamber volume not blocked by the casting piston.
2. The casting unit as claimed in claim 1, further characterized in that the casting material inlet opens out into the region of free space and/or into the casting material outlet.
3. The casting unit as claimed in claim 2, further characterized in that the casting material inlet and/or a casting material feed line (7) assigned to it is provided with a shut-off element (9), which prevents casting material from escaping from the casting chamber via the casting material inlet.
4. The casting unit as claimed in any one of claims 1 to 3, further characterized in that the casting chamber body comprises a hollow cylinder (1a) and the through-passage is provided at a face end of the hollow cylinder.
5. The casting unit as claimed in claim 4, further characterized in that the casting material outlet and/or the casting material inlet is provided at the face end of the hollow cylinder that is opposite from the through-passage or is provided at a cylinder lateral surface of the hollow cylinder.
6. The casting unit as claimed in any one of claims 1 to 5, further characterized in that a guiding sleeve (11) is provided for the casting piston, said sleeve extending outward from an outer side of the through-passage that is facing away from the casting chamber and/or extending from an inner side of the through-passage that is facing the casting chamber into the casting chamber.
7. The casting unit as claimed in any one of claims 1 to 6, further characterized in that a guiding sleeve temperature control device (12) is provided and/or a casting chamber temperature control device (13) for actively controlling the temperature of the casting chamber is provided.
8. The casting unit as claimed in any one of claims 1 to 7, further characterized in that a relieving annular groove (17) is provided on an inner wall of the through-passage or the guiding sleeve that is facing the casting piston, and a relieving channel (18) is provided leading from the relieving annular groove to the outer side of the casting chamber body.

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