EP0171779A2 - Device for surface treatment of workpieces growing brittle at low temperatures - Google Patents

Abstract

Cold-embrittled parts are surface treated by an abrasive jet through the use of an arrangement which includes as a centrifuge wheel. The centrifuge wheel is self-priming and is connected to a granulate collecting tank via a suction pipe with a spray nozzle for low boiling liquefied gas being arranged in the inlet zone of the suction pipe. The resulting abrasive jet pattern is of the same shape and size as the treatment surface.

Description

The invention relates to a device for the surface treatment of workpieces that can be embrittled by the cold. Surface treatments such as hardening and polishing should also be included.

A large number of devices are known for the surface treatment of workpieces which can be embrittled by cold. Common to all of these devices is a conveying device with which the workpieces are conveyed and circulated, a spray device for a low-boiling liquefied gas, usually nitrogen, and at least one centrifugal wheel for an abrasive such as 4 Cast steel or plastic granulate. Rotating drums, drum-like belts or rotating plates are known as conveying means. A device for deburring workpieces is known from German Offenlegungsschrift 26 50 202, in which the workpieces are conveyed on an oscillating trough which is provided with sieves for separating granules, coarse breakage and dust. The device is equipped with at least one centrifugal wheel which emits granules in the horizontal direction. The centrifugal wheel is surrounded by a conical baffle collar ring with a cone angle of approximately 90 °. The horizontally emitted granulate is reflected downwards by this impact collar ring onto the processing surface of the vibrating trough. The nozzles for the low-boiling liquefied gas are arranged on the edge of the impact collar ring. With this known device, the surface machining of workpieces that can be embrittled by cold can normally be carried out satisfactorily. The only exception is small and filigree molded parts, which are to be processed quickly and gently and usually only occur in small batches. Although the known device ensures that the kinetic energy of the granules hitting the work surface is the same everywhere, it cannot be avoided that the workpieces are irradiated for different lengths depending on their position on the work surface. This is irrelevant for most surface treatment work, as long as the desired effect, such as complete deburring, is achieved. Delicate, filigree molded parts are sensitive to different irradiation times. It has also been found that in certain cases such molded parts can be damaged by another effect.

The blasted granules are always circulated, which means that dust and coarse breakage have to be separated. This happens with seven. This does not, however, detect the break that has the size of the granules. This break is blasted along with the original granules and only gradually broken up after many passes. As a rule, this is completely irrelevant for surface processing. However, if this break is harder or has a greater density than the granulate, it can damage delicate filigree molded parts or molded parts with sensitive surfaces.

The invention is therefore based on the object to provide a device for surface treatment of cold-brittle workpieces, which, starting from the known device, enables even sensitive and small filigree molded parts, possibly in small batches, to be processed quickly and gently.

Starting from the prior art taken into account in the preamble of claim 1, this object is achieved according to the invention with the features specified in the characterizing part of claim 1. Advantageous developments of the invention are specified in the subclaims.

The device according to the invention is based on the one hand on the idea of making the machining surface identical in shape and size to the beam image. It is achieved in that the workpieces are not only irradiated by granulate particles with the same kinetic energy, but that the total number of incident granules for each workpiece is almost the same as it passes through the vibrating trough.

The measure according to the invention of arranging an additional spray nozzle for low-boiling liquefied gas in the inlet region of the intake pipe of the self-priming centrifugal wheel ensures that the granules which are captured by the centrifugal wheel are already deep-frozen.

The break promoted with the granules in the circuit is thereby embrittled and broken when it hits the impact collar rings, so that it can no longer damage the sensitive molded parts. Further advantages of the invention result from the following description of an embodiment. This is a surface processing device according to the invention, which can be manufactured in different sizes, but advantageously as a small system for processing small batches. The device will be explained with reference to the accompanying drawings.

• Fig.1 eine teilweise geschnittene perspektivische Darstellung der Strahleinrichtung und des Schwingtroges einer erfindungsgemäßen Einrichtung,
• Fig.2 eine gegenüber Fig.1 etwas abgewandelte Vorrichtung im Längsschnitt,
• Fig.3 einen Schnitt entlang der Linie A - B von Fig.2.

Show it:

• 1 is a partially sectioned perspective view of the beam device and the vibrating trough of a device according to the invention,
• 2 shows a somewhat modified device in longitudinal section compared to FIG. 1,
• 3 shows a section along the line A - B of Figure 2.

1 shows the inner part of a device according to the invention for the surface treatment of workpieces that can be embrittled by cold, consisting of the jet device and the vibrating trough. This inner part is in an isolation cell, not shown. The molded parts to be processed are filled via a slide 1 into the annular processing trough 2, which is part of the vibrating trough. The circular processing trough 2 represents the processing surface which is uniformly acted upon by the blasted granulate. Coarse waste, granules and dust fall through sieve openings in processing trough 2 into sieve trough 3 for coarse waste. Here the coarse waste is screened out, which is conveyed to the outside through a shaft 21, the bellows 19 and the dust and waste lock 16. Granules and dust enter the sieve trough 4 for granules, where the dust is sieved off. This falls into the dust trough 5 and also reaches the outside through the shaft 21, the bellows 19 and the dust and waste lock 16. The processing trough 2, the sieve trough 3 for coarse waste, the sieve trough 4 for granulate and the dust trough 5 together represent the vibrating trough. This is set in vibration by two unbalance motors 6. Due to the vibration, the molded parts are conveyed in the direction of the arrows 22 and turned and circulated by means of the internals 7, and the granules are separated from waste and dust. The separated granulate falls from the sieve trough 4 via a chute 23 into the collection container 13 for granulate. In the embodiment according to FIG. 2, the chute 23 is omitted, since here the inside diameter of the vibrating trough is reduced so that the granules can fall directly into the collecting container 13.

The jet device consists of the self-priming centrifugal wheel 11, which is driven by the motor 10. The centrifugal wheel sucks in the granules through the intake pipe 12 and radiates them onto the impact collar ring 9 in the horizontal direction. The impact collar ring 9 reflects the granules on the processing trough 2. At the edge of the baffle collar ring 9 spray nozzles 8 are attached for spraying liquid nitrogen. The finished molded parts reach the outside through the outlet 15. The embodiment according to FIGS. 2 and 3 differs from that according to FIG. 1 essentially only by the smaller inside diameter of the oscillating trough. The same designations were therefore used for the same parts, and the insulation cell 17 is also shown.

According to the invention, a spray nozzle 14 for liquid nitrogen is arranged in the inlet area of the intake pipe 12. The sucked-in granulate is cooled down strongly by the liquid nitrogen. This cooling has the effect that material particles, such as burrs or coating residues, which are the same size as the granules and therefore cannot be separated from the stream of granules by sieving, become brittle and are broken up on impact with the impact collar ring 9. It can therefore no longer happen that, in the case of materials whose density is greater than that of the granules, the molded parts are damaged because of the higher kinetic energy of the material particles which have been cut off. In addition, the device makes it possible to screen out the material residues that have been smashed in this way, which increases the purity of the circulating granules.

A particularly advantageous embodiment is obtained when the spray nozzle 14 is arranged below the inlet opening of the intake pipe, the axis of which in the flow direction. This arrangement intensifies the flow of granules into the intake pipe 12, whereby the amount of granules in circulation is increased. A further increase in the flow of granules is caused by the inlet nozzle 18 arranged at the inlet end of the suction pipe 12, which has the shape of a funnel and surrounds the suction pipe 12 with formation an annulus. The inlet nozzle 18 detects a part of the granulate flowing back from the sieve trough 4 into the collecting container 13 and conveys it into the intake pipe 12. In addition to the increase in the granulate flow, this results in a particularly good use of coolant, since preferably cooled granulate from the sieve trough 4 again into the intake pipe 12 arrives and the warmer granules are sucked out of the collecting container 13 to a reduced extent. The entire vibrating trough stands on spring elements 20. Bellows 19 are located at all transitions from vibrating to resting elements, so that no clamping points can arise in which the workpieces could be damaged.

By changing the vibration amplitude and the vibration frequency as well as by the shape of the internals 7 as tipping or rolling fast, the surface processing can be individually adapted to the most varied of molded parts. The connections to the outside through the insulation cell 17 are reduced to a minimum, the insulation effect is therefore high and the coolant requirement is low. This makes it possible to implement the device according to the invention as a small system for very small batches of molded parts. By changing the centrifugal wheel speed and the type and size of granulate, the most varied radiation energy densities can be achieved on the processing surface, so that a wide variety of materials, shapes and burr thicknesses can be taken into account. The processing time can also be largely varied.

Since there are no relative movements between the machining part and screening, blasting media can neither be scattered, nor can dust and cold gas leave the system unintentionally, which increases operational readiness.

As the rolling is generated by vibration and tilting or rolling on permanently installed parts, the parts cannot be pinched, as can happen with trough belts and drums, where particularly small and delicate parts can be crushed between moving and stationary elements.

Claims (3)

1.Device for the surface treatment of workpieces that can be embrittled by blasting with granules withdrawn from a collecting container and circulated and sprayed with low-boiling liquefied gas, with a centrifugal wheel (11) radiating granules in the horizontal direction, an impact collar ring (9) arranged around the centrifugal wheel for reflection the granulate onto the processing surface, spray nozzles (8) for the low-boiling liquefied gas and a processing surface which is part of a vibrating trough with sieves for separating granulate, coarse waste and dust,
characterized,
that the processing area corresponds in shape and size to the spray pattern, the centrifugal wheel is designed to be self-priming and is connected to the collecting container (13) for granulate by an intake pipe (12) and a spray nozzle (14) for low-boiling liquefied gas is arranged in the inlet area of the intake pipe . 2. Device according to claim 1,
characterized,
that the spray nozzle (14) is arranged below the inlet opening of the suction pipe in its axis in the direction of flow. 3. Device according to claim 1 or 2,
characterized,
that the inlet end of the intake pipe is surrounded by a funnel-shaped inlet nozzle (18) for granules in circulation, forming an annular space.

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