DE10306122B3 - Production of a metal cast housing comprises molding a sand core into a piece to be used as a detachable part, and pulling back a slide whilst the detachable part remains in its position in the undercut and removing the sand core - Google Patents

Abstract

Production of a metal cast housing comprises molding a sand core (36) into a piece to be used as a detachable part (74) which forms a contour for the part of the core, and pulling back a slide whilst the detachable part remains in its position in the undercut and removing the sand core with the detachable part from the core box. Preferred Features: The detachable part consists of two parts which move relative to each other. The detachable part has a main part forming the largest part of the contour and an additional part.

Description

The The invention relates to a method for producing a cast metal housing for pumps, with a spiral chamber, which is followed by a spiral Outside monotonously changing in cross section Spiral channel is formed, and with a curved, opening in the middle of the spiral chamber Suction neck, the one running approximately parallel to the plane of the spiral chamber upstream Section.

Methods for manufacturing such metal cast housings are e.g. B. from DE 100 50 448 A1 and EP 0 778 096 B1 known.

at the manufacture of cast metal housings the metal melt in an at least two-part, by a Cast upper box mold and a lower box mold formed sand mold, the one of the outer contour of the housing corresponding mold cavity forms. To form the inner contour of the housing will before closing a sand core is inserted into the mold and with the help of core marks fixed in the upper and lower box shapes. After the pouring process and the solidification of the melt will destroy the outer sand mold and the sand core removed.

The Sand core consisting of sand and binding agent is in turn a multi-part mold, a so-called core box.

In MENDEN, Albert: "Foundry Model Building", foundry publishing house, Dusseldorf 1991, pp. 64, 161, 162 describes a process for the production of the sand core described with the help of box-less parts.

On Problem in the production of metal cast housings with the one described above So far, geometry has been such that the sand core is not in one piece can be made because there is an undercut between the suction neck and the volute casing, which is shaped so that the sand core cannot be removed from the jail box even if the core box has side slides.

at a manufacturing method known from practice is therefore worked with a two-part sand core. Cores for the spiral chamber on the one hand and for the suction neck, on the other hand, are manufactured in separate core boxes and then inserted into each other before inserting the sand core into the mold. Consequently, the sand core points at the transition point between the suction neck and volute casing one Parting line that forms after dividing the housing as a dividing seam a slightly raised ridge on the inside surface of the case. Because this dividing seam in an inaccessible place Area inside the case, is a post-processing to remove the burr or not possible with unreasonably high effort. However, if the burr is not removed, it will result in use that made from the cast metal housing Pump an elevated flow resistance for the flowing through Medium.

The Invention with the features specified in claim 1 the advantage that a pump housing with a seamless inner surface and consequently with improved flow properties is created without a Post processing is required.

at the manufacture of the cast metal housing according to the invention a one-piece Sand core used. To enable the sand core to be demolded, a separate loose part is inserted into the core box, which the Forms undercuts between the spiral chamber and the suction neck. After opening of the core box, the sand core together with the loose part from the Core box removed. To detach the loose part from the sand core, to the loose part in the direction in which the cross section of the Spiral channel tapers, rotated around the axis of the spiral chamber. In this way the loose part comes free from the undercut so that it can be removed completely. As a borderline case, the method can also be used for housings in which the Spiral channel has a constant cross section. The expression "changing monotonously" is therefore too understand that the The cross section of the spiral channel does not alternately expand towards the outside and narrowed.

The use of a one-piece sand core has several notable advantages. On the one hand, a burr or a dividing seam on the inner surface of the cast metal housing cannot occur at all, since the sand core has no dividing joint at the transition between the suction neck and the spiral chamber. On the other hand, there is less work involved because it is no longer necessary to precisely insert the separately manufactured parts of the sand core and to align them carefully with one another. The one-piece sand core is also easier to handle, which is particularly advantageous if the sand core is inserted into the casting mold with the aid of an automatic core insert. Furthermore, the method according to the invention enables better dimensional accuracy (tighter tolerances) in the production of the cast metal housing, since there is no play between different core parts due to the one-piece construction of the sand core, and thus the risk of adjustment errors when assembling the core parts is avoided.

advantageous Further developments of the manufacturing process result from the dependent claims.

By Use of a lot part, which in turn consists of several relative mutually movable parts is assembled, a simple release of the Lots of sand core possible even with more complex geometry of the cast metal housing.

in the the following are embodiments of the Invention explained with reference to the drawings.

It demonstrate:

1 a cast metal housing in plan view;

2 a longitudinal section through the cast metal housing 1 ;

3 a view of a sand core for the manufacture of the metal cast housing after 2 ;

4 a plan of an upper part of a core box for the manufacture of the sand core 3 ;

5 a plan of a lower part of the core box;

6 an exploded view of the lower part of the core box;

7 a sketch of the sand core with a lot part;

8th a loose part according to another embodiment in a perspective view from below; and

9 the loose part after 8th in a perspective view from above.

This in 1 shown cast metal housing 10 is a pump housing with a spiral chamber 12 and a suction neck 14 , The spiral chamber 12 is through a spiral spiral channel 16 formed, the approximately circular cross-section, following the spiral course, continuously expanding from the inside to the outside. The spiral channel goes at the free end 16 into an outlet port 18 over that at the end a connecting flange 20 having. The suction neck 14 has an upstream section 22 by a connecting flange 24 goes out and swings slightly, approximately parallel to the plane of the spiral chamber 12 extends above this spiral chamber. To the section 22 a knee closes downstream 26 in the middle of the spiral chamber 12 empties.

How 2 shows, are the individual turns of the spiral channel 16 only by narrowing 28 delimited from each other, but their cross-sections are interconnected. On the mouth of the suction neck 14 opposite side of the spiral chamber 12 an opening 30 on which receives a bearing, not shown, for an impeller. The rotating pump wheel turns this over the suction neck 14 medium sucked into the spiral channel 16 and further into the outlet port 18 promoted.

The cast metal housing 10 is produced in a mold, of which in 2 the sand molds of an upper box mold 32 and a bottom box shape 34 are indicated by dash-dotted lines.

For shaping the inner contour of the suction neck 14 , the spiral chamber 12 and the outlet nozzle 18 serves a sand core 36 who in 3 is shown separately. This sand core 36 has a the cavity of the suction neck 14 forming suction neck core 14 ' and a the cavity of the scroll chamber including the outlet port 18 forming spiral chamber core 12 ' on. The spiral chamber core 12 ' exhibits a cylindrical approach 30 ' to shape the opening 30 on. The approach 30 ' a truncated cone-shaped core mark closes below 38 that fits into a corresponding recording 38 ' the bottom box shape 34 engages and serves to fix the sand core in the casting mold. At the free ends of the suction neck core 14 ' and the spiral chamber core 12 ' are truncated pyramid-shaped core brands 40 . 42 . 46 . 48 arranged in appropriate pockets 40 ' . 42 ' . 46 ' . 48 ' the bottom box shape 34 and the top box shape 32 intervention.

The sand core is according to the invention 36 molded in one piece from quartz sand mixed with binder. In contrast, a conventional two-part sand core is used, ie the suction neck core 14 ' and the spiral chamber core 12 ' are designed separately and are inserted into each other when the sand core is put together. As a result, the conventional sand core points at the seam between the suction neck core 14 ' and spiral chamber core 12 ' inevitably a small joint, which appears as a ridge or seam N on the inner surface of the cast metal housing 10 lays out as in 2 is indicated by dashed lines. Due to the one-piece formation of the sand core 36 the formation of this seam N is avoided according to the invention.

The sand core 36 points between the suction neck nuclear 14 ' and the spiral chamber core 12 ' an undercut 50 due to the spiral channel 16 formed reliefs can not be easily removed from the mold when molding the sand core 36 a core box with sliders is used, which is perpendicular to the drawing plane in 3 are movable.

The production of the one-piece sand core 36 is described below using the 4 to 7 explained.

4 shows in a view from below the upper part of a core box, which is used to form the sand core 36 serves. This upper part has a mold cavity 54 with which half of the spiral chamber core 12 ' as well as the core brand 40 be shaped. Because the sand core 36 with the suction neck core 14 ' lies in the core box downwards, the mold cavity serves 54 in the top 52 to shape the lower half of the spiral chamber core 12 ' in 3 , On an elevated plateau 56 has the top 52 a mold cavity 58 with which part of the suction neck core 14 ' and the core brand 42 be shaped.

5 shows an associated bottom part in a view from above 60 of the core box. There is a mold cavity in this lower part 62 formed with which part of the spiral channel core 12 ' and the core brand 46 be molded, as well as a mold cavity 64 for the suction neck core 14 ' and the core brand 48 , The two mold cavities 62 and 64 are separated by a breakthrough in the two sliders from opposite sides 66 . 68 are inserted so that they lie snugly against each other in the middle and completely fill the opening. The slider 66 . 68 are each on a movable support plate 70 respectively. 72 attached.

The slider 66 also takes a loose part 74 on. Through this lot 74 and the adjacent areas of the slider become the remaining parts of the sand core 36 shaped.

The design of the slider 66 . 68 and the lot part 74 is in the exploded view in 6 recognizable more clearly. The lot part 74 has a shape contour 76 which extends over a circumferential angle of slightly less than 180 ° and for forming a corresponding part of the spiral chamber core 12 ' serves. Furthermore, the lot part 74 one in 6 arm projecting vertically upwards 78 which has a handle at the free end 80 wearing.

The slider 66 points one to the loose part 74 adapted recording 82 on, which is designed so that the slide 66 up in 6 from the lot part 74 can be deducted. In addition, the slide forms 66 a quarter-circular shape contour 84 for part of the mouth of the sucker neck 14 ' in the spiral chamber core 12 ' , This shape contour goes on the underside of the slide 66 in an in 6 Invisible form contour for half of the knee of the suction neck core 14 ' about.

In the lower part 60 here is the breakthrough already mentioned 86 for the slider 66 and 68 to recognize.

The slider 68 has a recording 88 for the free end of the lot part 74 and a recording 90 for one in the breakthrough 86 projecting shape contour 92 that on the lower part 60 is formed and the shape contour 76 of the lot part 74 steadily continues. Furthermore, the slide has 68 another shape contour 94 for the outer peripheral area of the spiral chamber core 12 ' and - mainly on the underside - unspecified shape contours for the suction neck core 14 ' , Due to this arrangement of the shape contours, the slide can 68 even after shaping the sand core 36 easily from the lower part 60 pull out.

7 shows the central area of the sand core 36 - now in the same orientation as in 3 , with the suction neck core 14 ' upwards - in the state that exists when the core box has been opened and the slides have been withdrawn and the sand core has been removed from the core box. Because of the undercut 50 ( 3 ) becomes the loose part 74 when retracting the slider held so that it is still in the undercut 50 sitting. To the raffle 74 To detach from the sand core is now the arm 78 of the lot part grasped by hand and in the direction of the arrow, i.e. clockwise in 7 , around the central axis of the spiral chamber core 12 ' turned. This rotary movement is possible because of the diameter of the spiral channel 16 decreases in this direction, so that the shape contour 76 of the loose part from the peripheral surface of the spiral chamber core 12 ' is released. After the raffle 74 has been turned far enough so that it is out of the undercut 50 emerges, the loose part can be removed completely, so that the sand core 36 is completely removed from the mold.

Depending on the desired design of the interior of the cast metal housing 10 it can happen that the shape contour 76 of the lot must still have an undercut, which the in 7 prevent rotation of the loose part shown. This problem can be solved in that the loose part 74 in turn is composed of several parts. This is in 8th and 9 based on a lot 96 illustrates that a main part 98 and a supplementary part 100 having. The arm 78 is on the main part 98 educated. This main part 98 also forms the largest part of the shape contour 76 , as in 9 can be seen. The supplementary part 100 only forms a small part in the direction of rotation 7 rear end of the contour.

In 8th one looks at the side of the lot part 96 that are the top of the lot 74 in 7 equivalent. The supplementary part 100 is in 8th shown in partially released position. This supplementary part forms a contour 102 , which serves to make a rounded transition between the suction neck core 14 ' and the spiral chamber core 12 ' to shape. This contour would not be possible without an undercut on the slide 68 form, and if it were rigidly formed on the loose part, would prevent the loose part from being unscrewed. That is why the shape contour 102 on the supplementary part 100 trained that in an arcuate recording 104 of the main part 98 is kept and completely fills it in the final assembled state. The supplementary part 100 is, for example, with the help of magnets, not shown, on the main part 98 fixed and has a handle 106 , which allows the supplementary part 100 in the counterclockwise direction when demolding 8th from the space between the suction neck core 14 ' and the spiral chamber core 12 ' unscrewed. After that, the main part 98 of the lot part 96 as in 7 be turned out clockwise.

As in 9 is shown, limits the additional part 100 only the outer peripheral area of the spiral chamber core 12 ' , Because the cross section of the spiral channel 16 no longer enlarged here, the rotary movement of the additional part is on the by the recording 104 defined path of movement is not hindered.

Claims (3)

Process for the production of a cast metal housing ( 10 ) for pumps, with a spiral chamber ( 12 ), which is formed by a spiral-shaped spiral channel that changes monotonically in cross-section towards the outside ( 16 ) is formed, and with a curved, in the middle of the spiral chamber ( 12 ) opening suction neck ( 14 ) which is approximately parallel to the plane of the spiral chamber ( 12 ) upstream section ( 22 ) with the following steps: a) forming a sand core ( 36 ) in the form of through the spiral chamber ( 12 ) and the suction neck ( 14 ) formed cavity of the cast metal housing, with the help of a multi-part core box ( 52 . 60 ), which has a mold cavity for the sand core ( 36 ) forms, b) demoulding of the sand core ( 36 ) from the core box ( 52 . 60 ), c) inserting the sand core ( 36 ) in a mold ( 32 . 34 ), which has a mold cavity corresponding to the outer contour of the cast metal housing ( 10 ) forms, d) filling the mold cavity of the casting mold ( 32 . 34 ) with molten metal and e) after solidification of the melt, demolding of the cast metal housing ( 10 ) destroying the sand core ( 36 ), characterized in that in step (a) the sand core ( 36 ) is formed into one piece, for which a loose part ( 74 ; 96 ) is used that has a shape contour ( 76 ) for the part of the sand core ( 36 ) that forms the inner wall of the spiral chamber ( 12 ) in the area of an undercut ( 50 ) between the spiral chamber ( 12 ) and the suction neck ( 14 ) forms while adjacent parts of the sand core are moved by slides that are guided in the core box ( 66 . 68 ) are shaped so that in step (b) the slide ( 66 . 68 ) be withdrawn while the lottery part ( 74 . 96 ) in its position in the undercut ( 50 ) remains, and that after the sand core ( 36 ) with the lot part ( 74 ; 96 ) from the core box ( 52 . 60 ) was removed, the lot part ( 74 ; 96 ) from the sand core ( 36 ) is solved by turning it in the direction of rotation in which the diameter of the spiral channel ( 16 ) decreases around the central axis of the part forming the spiral chamber ( 12 ' ) of the sand core is rotated. A method according to claim 1, characterized in that the loose part ( 96 ) of two parts that are movable relative to each other ( 98 . 100 ) is composed. Method according to claim 2, characterized in that the loose part ( 96 ) a main part ( 98 ) which covers most of the contour of the shape ( 76 ) forms, and a supplementary part ( 100 ) that only has a small part of the shape contour ( 76 ) forms at the rear end of the loose part when demolding in the direction of rotation, and that the supplementary part ( 100 ) when demolding in the direction of rotation of the main part ( 98 ) is turned in the opposite direction.