EP0106220A2 - Apparatus for controllably conducting gaseous media - Google Patents

Abstract

A device for compressing granular molding materials, in particular foundry molding materials, is proposed, in which a plurality of tubular hollow bodies are arranged between the pressure vessel and the molding box in the direction of action of the pressure surge in order to pass the gaseous medium onto the top of the molding material. By dividing the passage cross-section into several independent cross-sections, the stroke for opening the valve is considerably reduced and the sealing element is thus opened quickly.

Description

The invention relates to a device for compacting granular molding materials, in particular foundry molding materials, a pressure surge of a gaseous medium being applied to the surface of a molding material mass loosely poured over a model device.

For the passage of gases, in particular compressed air, devices are also known, among other things, in which a passage covers a passage opening by means of a membrane or a plate-shaped shut-off device, and thus a closing or opening of the passage cross section is achieved.

In all of these arrangements, the passage cross section determines; taking advantage of the full passage, the stroke of the sealing member, be it a membrane, a valve disk or the like.

It therefore applies that the larger the cross section, the greater the stroke.

A large stroke, however, is hardly achievable in the short-term sequence with large-sized passages and especially with quick-opening facilities.

Starting from the prior art, it is an object of the invention to provide a device with which the stroke, even with large passage cross sections, can be kept to a minimum and the full throughput achieved can be achieved with working times of the smallest size.

This object is achieved by the teaching specified in the claim.

Further features and details of this teaching are shown in the additional claims.

With the arrangement of the hollow bodies projecting into the pressure chamber and thus the division of the passage cross-sectional area into individual cross-sections, independent passages are formed with the hollow bodies, which in the operating state are acted upon all around by the pressure medium to be conveyed. Thus, only the passage cross section of the individual hollow body is decisive for the determination of the stroke of the sealing member and thus the stroke is relatively small and consequently the opening time of the passage is minimal.

Exemplary embodiments according to the invention are described in more detail below with reference to the drawing.

• Fig. 1 eine Einrichtung mit einem Dichtorgan als Plattenkolben,
• Fig. 2 einen Querschnitt durch die Hohlkörperanordnung von Fig. 1 nach der Linie A - A,
• Fig. 3 eine Variante der Einrichtung mit geschlossenem Dichtorgan, und
• Fig. 4 eine weitere Variante der Einrichtung mit einem membranenartigen Dichtorgan und mit Einsatz an einer,Formverdich- tungseinheit.

Show it:

• 1 shows a device with a sealing member as a plate piston,
• 2 shows a cross section through the hollow body arrangement of FIG. 1 along the line A - A,
• Fig. 3 shows a variant of the device with a closed sealing member, and
• FIG. 4 shows a further variant of the device with a membrane-like sealing element and with use on a compression molding unit.

Figures 1 to 4 show designs which have the same inventive feature, according to which a sealing plane 1 is formed from ends 5 of a plurality of hollow bodies 2. The hollow bodies 2 are in this case inserted separately from one another in a housing 3 and thereby form, with their spacing, cavities 4 which, with the interior 15 of the housing, result in an undivided space. The openings 6 facing away from the sealing plane 1 open outward from the housing 3, into a molding space above a molding material mass. The arrangement of the hollow bodies 2 is such that their longitudinal axes run parallel to one another. However, it is also possible to provide the axes radiating to one another. The ends 6 of the hollow body 2 facing away from the sealing plane 1 are sealed and form part of the housing 3 thus part of the housing wall. The length and the distance of the hollow bodies 2 projecting into the pressure chamber and thus the space between the hollow bodies 2 depends on the total cross section from the large number of hollow body through-sections. Pointing the way, the condition of a low-loss flow through a pressure medium should be met.

In Fig. 1, a plate-shaped piston is provided as a sealing member 7 which is designed with one or more pocket-shaped recesses 8 in order to save weight and is preferably coated on the sealing side with an elastomer.

This piston is inserted in a sealing housing 9 in such a way that it is loosely guided to the circumferential inner surface 10 of the sealing housing with little play. A suitable clearance has been found to be 0.1 - 0.3 mm.

In order to influence the guiding property, the circumferential outer surface of such a piston can also be made cambered.

The sealing housing 9 is connected to the device housing 3 via struts 11. To apply a pressure gas to the piston 7 e.g. Compressed air leads a control line 12 through the housing cover 14 into the sealing. housing 9, and can be connected via a valve 13 to a control device, not shown. The valve 13 can be operated pneumatically, hydraulically or electrically.

The tube ends 5 of the hollow bodies 2 combined in the sealing plane 1 are treated as a sealing surface.

The openings 6 of the hollow body 2 facing away from the sealing plane 1 open into an outlet part 16 of the housing 3 and are tightly connected at their periphery to a bottom part 17 of the housing 3. In the present embodiment, this outlet part 15 has a flange connection 18 which is designed for connection to an exemplary shaping device. Other common connection options can also be used. Urgently sideways into the housing interior 15, a feed line 19 is provided for the pumped medium, which can optionally be equipped with a valve 20.

FIG. 2 shows a cross section through the hollow body arrangement 2 from FIG. 1 along the line A - A. Therein, the hollow bodies 2 are arranged as tubes with partly the same, partly unequal round cross section. However, it is easily possible to design the hollow body with a polygonal cross-section and / or with a conical widening in the direction of the longitudinal axis. The axes of the hollow bodies 2 are provided running parallel to one another. The horizontal cross sections of the hollow bodies 2 and, accordingly, the cross sections of the interstices 4 between the hollow bodies 2 largely depend on the flow pattern of the conveyed medium. From a fluidic point of view, it can be advantageous to vary the hollow body cross sections from the outside inwards, based on a bundle of hollow bodies. Larger hollow body cross-sections 21 are advantageously divided by transverse webs 22, whereby a distribution of the contact pressure of the sealing member 7 is achieved.

Figure 3 shows a similar design as shown in Figure 1. The hollow bodies 2a are arranged in the form of a beam, and they can be designed to be cylindrical as well as flared. The sealing element 7a resting in the sealing plane 1 on the hollow body ends 5a is designed as a self-contained sealing element. In this sealing member 7a, the inside toward the sealing plane 1 is provided with a reinforcing plate 27 for receiving the sealing pressure. In order to avoid excessive mass forces, the reinforcing plate 23 made of light metal or plastic is provided in a suitable shape. In order to largely ensure dimensional stability in the depressurized state on the inside of the sealing member 7a, a material is selected for this which has sufficient inherent rigidity and is nevertheless flexible. Armored elastomers are preferably used.

There is also the possibility of filling the cavity 24 of this sealing element 7a with a pasty mass or a suitable liquid or in some other way in order to improve the rigidity in the depressurized state and to keep the cavity as low as possible.

The housing 3a used here has on the top 25 a sealing housing 9a for the sealing member 7a. This sealing housing 9a is advantageously detachably connected to the housing 3a. A supply line 26 for the conveyed medium, for example compressed air, is provided on the side of the housing 3a. This feed line 26 is equipped with a valve 27, with which the feed line 26 can be closed or opened or throttled. The output ends 28 of the hollow body 7a open into a cylindrical outlet part 29 which is equipped with a flange for connection to a connecting part 30. The ends 28 are in this case connected to the outlet part 29 in a sealing manner with a base part 31. However, it is also possible to connect the ends 28 of the hollow bodies 7a directly to the housing base 32 without switching on an outlet part 29. Here, too, the requirement must be met that the sum of the spaces between the hollow bodies 7a is at least as large as the total cross-sectional area from the plurality of hollow body passage cross sections. This ensures an unimpeded flow of the medium.

FIG. 4 shows an embodiment which is designed with a molding device for the production of casting molds.

The upper part of the housing 3b is covered with a cover 37 in which the sealing plane 1 is located. The sealing plane 1 is in this case, similar to FIG. 1, formed by a plurality of ends 5b of hollow bodies 2b which are separated from one another and run in the direction of action of the medium delivery. The ends 5b of the hollow body 2b are also designed as a sealing surface.

The outlet ends 33 of the hollow body 2b are tightly connected on their outer circumference to a bottom part 34 of an outlet part 35. The outlet part 35 is in turn assembled with a bottom part 36 of the housing 3b and thus delimits a housing interior 41 together with the cover 37 and a sealing member 7b.

As a sealing member 7b, a plate is provided as a membrane, which is received circumferentially on the one hand on the housing cover 37 and on the other hand on the sealing cover 38. To act upon the membrane 7b with control air, a control line 39 leads through the cover 38 and can be actuated via a valve 40. The valve 40 can be actuated pneumatically, hydraulically as well as electrically. In the side of the housing wall there is a supply line 42 for a conveying medium, e.g. Compressed air, provided. Depending on the application, a valve 43 inserted in the supply line 42 enables a constant or interrupted supply of compressed gas to the interior 41 of the housing.

The device shown as a combination with a molding device shows the housing 3b which is designed with its lower end for coupling to the molding device.

The molding device consists of a filling frame 44, a molding frame 45 and a model unit 46 as well as a cylinder arrangement 47 for raising and lowering this combination.

Designated at 48 is a molding material, via the filling rate of which a vent line 49 with valve 50 is provided in the housing 3b. The compressed gas remaining after the inflow over the molding material can thus be released before the molding device is lowered. The combination is then separated.

The functional sequence of the device according to the invention is as follows. Assuming that a gas shaped medium must be transported, a pressure medium is exerted by the control line with a predetermined pressure on the sealing member and this is brought to the sealing system on the sealing surface. Subsequently, a delivery medium is brought into the housing, ie into the pressure chamber, through the supply line, and the device is thus prepared for passing the delivery medium through or for achieving a pressure surge.

It is readily possible to provide the pressure of the control medium equal to that of the conveying medium, the media being able to be of the same type.

If there is now a pressure drop in the control line by actuating the control valve, the pressure previously acting as a larger force on the control side of the sealing element is reduced, as a result of which the force acting on the pressure chamber side of the sealing element increases and the sealing element suddenly lifts and exceeds when the equilibrium state is exceeded so that the fluid can escape as a pressure surge.

By varying the actuation of the sealing member, the pressure surge effects can be changed, whereby both the pressure intensity and the quantity intensity can be varied.

Claims (12)

1.Device for compacting granular molding materials, in particular foundry molding materials in a closed system by the action of a pressure surge of a gaseous medium on the surface of a molding material mass loosely poured into a mold frame over a model plate, the closed system being formed by a pressure chamber and a molding device are connected to one another by a passage which can be opened or closed by a shut-off device, characterized in that the passage is formed by individual open hollow bodies (2, 2a, 2b) which run in the passage direction and are spaced apart in the pressure chamber, the hollow bodies ( 2, 2a, 2b) project with one end over part of their length into the pressure chamber and with the other end are directed towards the molding device, and the openings of the ends projecting into the pressure chamber can be covered by a common sealing element. 2. Device according to claim 1, characterized in that the hollow body (2, 2a, 2b) tubular with a round or polygonal cross section. 3. Device according to claim 1 and 2, characterized in that the hollow body (2, 2a, 2b) are flared towards the mold-side ends. 4. Device according to claim 1 to 3, characterized in that the axes of the hollow body (2, 2b) are arranged substantially parallel to each other. 5. Device according to claim 1 to 4, characterized in that the hollow body (2a) are arranged in a radiation shape. 6. Device according to claim 1 to 5, characterized in that the hollow body (2, 2a, 2b) have the same and / or different cross sections to each other. 7. Device according to claim 1 to 6, characterized in that the hollow body (2, 2a, 2b) are arranged concentrically. 8. Device according to claim 1 to 7, characterized in that the length of the hollow body (2, 2a, 2b) projecting into the pressure chamber can be acted upon by the conveying medium all around. 9. Device according to claim 1 to 8, characterized in that the sealing member is pneumatically controllable. 10. Device according to claim 1 to 9, characterized shows that the pressure of the gaseous medium on the control side and on the pressure chamber side of the sealing element (7, 7a, 7b) is the same. 11. The device according to claim 1 to 10, characterized in that the pressure in the pressure chamber is adjustable. 12. The device according to claim 1 to 11, characterized in that the stroke of the sealing member (7, 7a, 7b) and thus the amount of passage of the medium is adjustable.

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