WO2012016878A1 - Device for drying workpieces after a cleaning operation - Google Patents

Abstract

In order to provide a device for drying workpieces after a cleaning operation, comprising a vacuum chamber for the vacuum drying of a workpiece to be dried, which makes it possible for a workpiece that is to be dried to be dried largely without any residual soiling, it is proposed that the device comprises at least one blowing nozzle which opens out in the vacuum chamber and by means of which the workpiece to be dried can be exposed to a blowing medium.

Description

 Device for drying workpieces after a cleaning process

The present invention relates to a device for drying

Workpieces after a cleaning process, wherein the device comprises a vacuum chamber for vacuum drying a workpiece to be dried.

Such devices are used in particular for drying workpieces after cleaning in an aqueous cleaning system. The drying is usually carried out by blowing air generated by fans or compressed air in a blowing zone and subsequent vacuum drying in a vacuum chamber.

However, there is a great risk that the cleaned workpieces are contaminated by dirt particles in the blowing zone again.

Due to the relatively short residence time of the workpieces in the blowing zone, the flow velocity of the blown air must be very high. Due to this high flow velocity, dirt particles are entrained and led to the workpieces to be dried, which leads to the risk of recontamination of the workpieces.

The present invention has for its object to provide a device for drying workpieces after a cleaning process of the aforementioned type, which allows a largely backwashing-free drying of a workpiece to be dried. This object is achieved in a device having the features of the preamble of claim 1 according to the invention in that the device comprises at least one opening in the vacuum chamber blowing nozzle, by means of which the workpiece to be dried can be acted upon with a blowing medium.

The solution according to the invention is based on the concept of performing a blow-off process on the workpiece to be dried within the vacuum chamber used for the vacuum drying.

By performing the blow-off in the vacuum chamber, the risk of re-contamination of the workpiece to be dried is significantly reduced.

Preferably, the device according to the invention for drying workpieces has no blowing zone arranged outside the vacuum chamber for blowing off the workpiece. In this case, the workpiece to be dried is introduced into the vacuum drying chamber immediately after the cleaning process. Recovering from a pre-drying process in a separate blowing zone is thereby excluded.

The position and / or the outlet direction of the blowing medium from the blowing nozzle is preferably adjustable, so that the blowing medium jet generated by means of the blowing nozzle can be directed in particular to recesses on the workpiece to be dried, in which cleaning liquid still adhering to the workpiece is located.

In principle, any fluid medium, for example ambient air, compressed air or a vapor, can be used as blowing medium. If the blowing medium has a temperature which is elevated in relation to the room temperature, this has the advantage that undesired cooling of the workpiece during the drying process is avoided.

In particular, the device according to the invention for drying workpieces may comprise a device for heating the blowing medium. The heating of the blowing medium avoids a desired cooling of the workpiece during the drying process.

In a preferred embodiment of the invention it is provided that the device for drying workpieces comprises a device for generating blowing medium pulses. By means of such Blas medium pulses, in particular by means of compressed air pulses, in particular critical points that are not dry by the vacuum drying process alone, can be applied to distribute the adhering to these areas detergent over a large area over the workpiece surface. Subsequently, the heat energy stored in the workpiece supports the drying by the vacuum process.

The blowing medium pulses preferably have a duration of about 1.0 second or less.

The pulsed blowing off of the workpiece can take place before, during and / or after the vacuum drying process.

The ventilation of the vacuum chamber after the vacuum drying can be done in an easy-to-control manner and largely pollution-free, if the vacuum chamber is ventilated by at least one blowing nozzle. In order to prevent dirt particles from the blowing medium contaminating the workpiece to be dried, the device preferably comprises at least one fine filter, through which a blowing medium can be fed to at least one blowing nozzle.

The fine filter preferably has a filter fineness of about 10 μm or less, preferably about 5 μm or less. The filter fineness specifies the particle size at which particles are retained by the filter.

The fine filter can in particular be designed as a HEPA filter (High Efficiency Particulate Air Filter).

In order to easily clean the interior of the vacuum chamber and thus avoid accumulation of dirt within the vacuum chamber, through which the workpiece to be dried could be contaminated again, it is advantageous if the device comprises at least one opening in the vacuum chamber cleaning nozzle.

Through the cleaning nozzle is a, preferably liquid, detergent dispensable in the interior of the vacuum chamber.

In this case, at least one of the cleaning nozzles can be designed to be rotatable so that the largest possible area of the interior of the vacuum chamber can be acted upon by the cleaning agent through this cleaning nozzle.

In order to be able to remove cleaning agent and / or condensate arising in the interior of the vacuum chamber from the interior of the vacuum chamber, the vacuum chamber may comprise at least one liquid drain. Preferably, the liquid discharge is formed so that liquid from a deepest point of the interior of the vacuum chamber through the liquid discharge from the vacuum chamber can be discharged.

The vacuum chamber is preferably formed so that its inner wall runs as close as possible to the outer contour of the workpiece to be dried, so that only a small gap between the surface of the workpiece to be dried and the inner wall of the vacuum chamber remains. This ensures that the vacuum chamber is rapidly evacuated and that in the interior of the vacuum chamber outside the workpiece remains little dead space in which dirt particles can accumulate.

Preferably, the free volume of the interior of the vacuum chamber, that is, the total evacuatable volume of the interior of the vacuum chamber, is at most about 200%, preferably at most about 150%, of the volume occupied by the workpiece to be dried, in this definition that of the part to be dried Workpiece occupied volume to the free volume of the interior of the vacuum chamber counts.

In order to prevent liquid, in particular condensate, from accumulating on a part of the interior of the vacuum chamber located above the workpiece to be dried and allowing it to drip down onto the workpiece, it is favorable if at least one perpendicular to the workpiece, which is located in one Working position is located within the vacuum chamber, arranged part of an inner wall of the vacuum chamber inclined to the horizontal and / or curved.

It is particularly favorable if substantially the entire inner wall of the vacuum chamber is inclined and / or curved relative to the horizontal. For example, it can be provided that the vacuum chamber comprises a substantially cylindrical base body.

For the loading of the vacuum chamber with the workpiece to be dried, it is advantageous if the device comprises a workpiece holder, which is arranged between a working position within the vacuum chamber and a loading position in which the workpiece holder at least partially, preferably substantially completely, outside the vacuum chamber , is movable.

In a preferred embodiment of the invention it is provided that the device for drying workpieces comprises a lid which is movable together with the workpiece holder and closes an access opening of the vacuum chamber when the workpiece holder is in its working position.

In one embodiment of the device according to the invention it is provided that the vacuum chamber has a longitudinal direction, which is aligned substantially horizontally during the introduction of the workpiece to be dried in the vacuum chamber.

The direction of movement of the workpiece holder from the loading position to the working position is preferably aligned substantially parallel to this longitudinal direction of the vacuum chamber.

The longitudinal direction of the vacuum chamber is preferably the direction of an axis of symmetry of the vacuum chamber and / or a direction in which the expansion of the vacuum chamber is greatest. In an alternative embodiment of the invention it is provided that the device for drying workpieces has a longitudinal direction, which is aligned substantially vertically during the introduction of the workpiece to be dried in the vacuum chamber.

In particular, in order to buckling scooping parts of the workpiece to be dried before vacuum drying and / or during vacuum drying, it is advantageous if the vacuum chamber has a longitudinal direction whose orientation, in particular by a device for rotating or tilting the vacuum chamber, is variable , in particular rotatable and / or tiltable, while the workpiece is disposed within the vacuum chamber.

Preferably, the orientation of the longitudinal direction is variable after the introduction of the workpiece into the vacuum chamber and / or before the removal of the workpiece from the vacuum chamber.

In particular, it may be provided that the longitudinal direction of the vacuum chamber by 45 ° or more, preferably by about 90 °, for example, from a horizontal to a vertical orientation or from a vertical to a horizontal orientation, is rotatable or tiltable.

The present invention further relates to a method for drying workpieces after a cleaning process.

The invention is based on the further object of providing a method for drying workpieces after a cleaning process, in which a recontamination of a workpiece to be dried is largely avoided. This object is achieved by a method for drying workpieces after a cleaning process, which comprises the following method steps:

Introducing a workpiece to be dried into a vacuum chamber;

Applying pressure to the workpiece within the vacuum chamber with a blowing medium through at least one blowing nozzle;

Evacuating the vacuum chamber to perform vacuum drying of the workpiece;

Venting the vacuum chamber;

Discharging the workpiece from the vacuum chamber.

The said method steps can also be carried out in a different order than in the order of the above enumeration.

In a preferred embodiment of the method according to the invention it is provided that the ventilation of the vacuum chamber is carried out with a venting gas under increased pressure. This vent gas expands upon entry into the vacuum chamber, which cools the vent gas and, in turn, cools the dried work piece. By this cooling of the workpiece within the vacuum chamber during aeration of the same, the difference of the workpiece temperature is reduced by the room temperature, so that a subsequent cooling process of the workpiece inside or outside the vacuum chamber can be shortened or eliminated altogether.

Preferably, the pressure of the venting gas is at least about 1 bar, preferably at least about 5 bar, above the atmospheric pressure of the ambient atmosphere. The combination of blow-off of the workpiece and vacuum drying of the workpiece in the same vacuum chamber increases the efficiency of the drying process.

The energy required for the drying process is reduced, and drying is largely free of contamination.

Further, a vacuum pump with lower power can be used for the evacuation of the vacuum chamber.

Further features and advantages of the invention are the subject of the following description and the drawings of exemplary embodiments.

In the drawings show:

1 shows a schematic side view of an apparatus for drying workpieces after a cleaning process, the apparatus comprising a vacuum chamber with a longitudinal axis oriented substantially horizontally when introducing a workpiece to be dried into the vacuum chamber;

FIG. 2 shows a schematic cross section through the vacuum chamber with the workpiece arranged therein, along the line 2 - 2 in FIG. 1; FIG. 3 shows a schematic side view of a second embodiment of the device for drying workpieces after a cleaning process, wherein the device comprises a vacuum chamber with a longitudinal direction substantially aligned when introducing the workpiece to be dried into the vacuum chamber; and

4 shows a schematic cross section through the vacuum chamber and the workpiece arranged therein from FIG. 3, along the line 4-4 in FIG. 3.

Identical or functionally equivalent elements are denoted by the same reference numerals in all figures.

1 and 2, designated as a whole by 100, for drying workpieces after a cleaning process comprises a vacuum chamber 102 which comprises, for example, an essentially cylindrical base body 104, which is closed at one end by a, for example, conical closure section 106 ,

On the side opposite the closure section 106, the vacuum chamber 102 has an access opening 108, for example substantially circular, which can be closed by means of a cover 110.

The lid 110 is connected to a workpiece holder 112, which has a locking device 114 for locking a workpiece 116 to be dried on the workpiece holder 112.

The workpiece holder 112 and the cover 110 are together from a loading position shown in solid lines in FIG. 1, in which the workpiece holder 112 at least partially, preferably substantially completely, is arranged outside the vacuum chamber 102, movable into the working position shown in Fig. 1 in broken lines, in which the workpiece holder 112 is disposed completely in the interior 118 of the vacuum chamber and the lid 110 closes the access opening 108 of the vacuum chamber 102 substantially gas-tight.

To move the workpiece holder 112 and the cover 110 from the loading position to the working position and back from the working position back to the loading position is a movement device 120, of which in Fig. 1, only a guide device 122 is shown.

The guide device 122 may comprise, for example, a guide rod 124 connected to the cover 110, which passes through guide bores 126, which are provided, for example, on a respective guide plate 128.

The movement device 120 further comprises a motor drive (not shown), for example an electromotive, pneumatic or hydraulic drive, which engages in particular on the guide rod 124 to the same in its longitudinal direction, which is parallel to the direction of movement 130 of the workpiece holder 112 and the lid 110, to move.

The direction of movement 130 is substantially parallel to one

The longitudinal direction 132 of the vacuum chamber 102 and (in the position of the vacuum chamber 102 shown in FIG. 1) are aligned substantially parallel to the horizontal 134.

The longitudinal direction of the vacuum chamber 132 runs in particular parallel to a longitudinal center axis of the cylindrical basic body 104 of the vacuum chamber 102. In order to be able to evacuate the vacuum chamber 102 in the closed state, in which the cover 110 closes the access opening 108 of the vacuum chamber 102, the device 100 further comprises a vacuum generator 138, for example in the form of a vacuum pump 140, which is connected to the interior 118 via an evacuation line 142 the vacuum chamber 102 is connected.

In the evacuation 142 a shut-off valve 144 is arranged.

In order to be able to apply a blowing medium to the workpiece 116 arranged in the vacuum chamber 102, the device 100 further comprises a blowing device 146 with a plurality of blowing nozzles 148 opening in the vacuum chamber 102, whose outlet openings 150 are directed onto the surface of the workpiece 116 to be dried, if the workpiece 116 is in the working position in the interior 118 of the vacuum chamber 102.

The blowing nozzles 148 are connected to a distribution channel 152 into which a blowing medium supply line 154 opens.

The distribution channel 152 may be disposed outside the vacuum chamber 102.

The distribution channel 152 may in particular be arcuate and, with respect to the longitudinal central axis 136 of the vacuum chamber 102, extend over a circumferential angle of at least approximately 90 °, preferably at least approximately 120 °, in particular at least approximately 180 °.

The blowing nozzles 148 are preferably directed from several sides, in particular of at least three sides, onto the workpiece 116 to be dried. In the blowing medium supply line 154, a shut-off device 156 is arranged.

The obturator 156 is controllable by a control device (not shown) of the device 100 in a blow-off phase of the drying process so that it releases the blowing medium supply line 154 during a short period of time, for example about 0.5 sec to about 0.1 sec, so that the tuyeres 148 deliver a corresponding short blowing medium pulse to the workpiece 116.

In the blow-off phase, several such short blowing medium pulses can be generated.

During a ventilation phase of the device 100, the obturator 156 is controllable by the control device so that it releases the blowing medium supply line 154 until substantially the same pressure as in the outer space of the vacuum chamber 102 is reached in the interior space 118 of the vacuum chamber 102 and thus the vacuum chamber 102 is ventilated is, so that the access opening 108 can be opened again.

Further, in the blowing medium supply line 154, a fine filter 158 is arranged, through which the blowing medium is filtered before it is discharged via the tuyere 148 to the workpiece 116.

The fine filter 158 may be located downstream or upstream of the obturator 156.

The fine filter 158 is a filter having a filter fineness of, for example, about 10 μηη or less, preferably about 5 μηη or less.

The filter fineness specifies the particle size at which particles are retained by the filter. Preferably, the fine filter 158 is formed as a close-meshed fine filter.

The fine filter 158 may in particular be designed as a HEPA filter (High Efficiency Particulate Air Filter). Such a filter has the filter class H 10 according to the European standard EN 1822-1: 1998 or better.

The blowing medium supply line 154 is connected to a blowing medium source 160.

The blowing medium source 160 can be, for example, a compressed-air source, from which the compressed-air feed line 154 compressed air can be supplied at a pressure which is higher than the atmospheric pressure.

Such a compressed air source may in particular be a compressed air network of a production facility.

The compressed air in this case preferably has an overpressure relative to the atmospheric pressure of about 1 bar or more, in particular of about 5 bar or more.

Alternatively, it can also be provided that the blowing medium source 160 is formed by the ambient air in the outer space 162 of the vacuum chamber 102.

In this case, the supplied blowing medium has the atmospheric pressure.

Further, the blowing medium source 160 may be a generation and / or storage device of a vapor. The vapor preferably has a temperature above the ambient temperature. This ensures that the charged with the blowing medium workpiece 116 does not cool or the workpiece 116 is even heated by the blowing with the blowing medium, which promotes the drying of the workpiece 116.

For the same purpose can also be provided that the blowing device 146 has a device (not shown) for heating the blowing medium, when the blowing medium is formed for example by ambient air or by compressed air.

The feeding of the blowing medium into the vacuum chamber 102 takes place in such a way that no dirt particles in the inner space 118 of the vacuum chamber 102 are whirled up. As a result, contamination of the workpiece to be dried 116 with dirt from the vacuum chamber 102 is avoided.

The entry of the blowing medium into the vacuum chamber 102 takes place from above and from the side, but preferably not from below. This also avoids contamination of the workpiece 116 to be dried with dirt particles that could be carried by the blowing medium to the workpiece 116.

The blowing nozzles 148 are adjustable (manually or by motor) with regard to the position and the orientation of their nozzle outlet openings, in order to be able to direct the blowing-medium jets to specific desired locations on the surface of the workpiece 116 to be dried.

It is particularly favorable if the blowing nozzles 148 are adjustable so that the blowing medium beams generated by them are directed to recesses, for example deep holes, on the workpiece 116, since such recesses form critical points which may not be sufficient by vacuum drying alone be dried. The vacuum chamber 102 is designed such that its inner wall 164 runs as close as possible to the outer contour of the workpiece 116 to be dried, so that the smallest possible gap between the surface of the workpiece 116 to be dried and the inner wall 164 of the vacuum chamber 102 remains. In this way it is achieved that the vacuum chamber 102 is rapidly evacuated and that in the interior 118 of the vacuum chamber 102 outside the workpiece 116 remains only little dead space, in which

Can accumulate dirt particles.

Preferably, the free volume of the inner space 118 of the vacuum chamber 102, that is, the total evacuatable volume of the inner space 118, is at most about 200%, preferably at most about 150%, of the volume occupied by the workpiece 116 to be dried (note that FIG this definition of the free volume of the interior 118 of the vacuum chamber 102, the volume occupied by the workpiece 116 to be dried during operation of the apparatus 100 forms part of this free volume).

Furthermore, the interior of the vacuum chamber 102 is designed so that no dirt can accumulate and drops of liquid, in particular condensate, do not fall onto the workpiece 116.

This is achieved in the embodiment of the vacuum chamber 102 shown in FIGS. 1 and 2 in particular in that the inner wall 164 of the vacuum chamber 102, in particular the part of the inner wall 164 arranged vertically above the workpiece 116 located in the working position, is curved. In order to prevent accumulation of dirt in the interior 118 of the vacuum chamber 102, the device 100 further comprises a cleaning device 166, by means of which the interior space 118 of the vacuum chamber 102 can be cleaned.

The cleaning device 166 may in particular comprise one or more rinsing nozzles or cleaning nozzles 168, which are arranged in the inner space 118 of the vacuum chamber 102 and by means of which a, preferably liquid, cleaning agent can be dispensed into the inner space 118.

At least one of the cleaning nozzles 168 may in particular be designed to be rotatable so that the largest possible area of the interior 118 of the vacuum chamber 102 can be acted upon by the cleaning agent through this cleaning nozzle 168.

The rotational movement of the relevant cleaning nozzle 168 is preferably driven by a motor.

The cleaning nozzle 168 is connected to a detergent reservoir 172 via a detergent supply line 170.

In the detergent supply line 170, a shut-off device 174 is arranged.

In order to be able to remove the condensate arising in the interior 118 of the vacuum chamber 102 from the interior space 118, the vacuum chamber 102 is further provided with a liquid outlet 176.

The liquid outlet 176 preferably opens at a lowest point of the inner space 118 of the vacuum chamber 102 into this inner space 118. Furthermore, the liquid outlet 176 is provided with a shut-off device 178.

The above-described apparatus 100 for drying workpieces after a cleaning operation functions as follows:

The workpiece 116 is cleaned in a device 100 upstream of the cleaning device, preferably after a machining operation.

The workpiece 116 is preferably a metallic workpiece.

In particular, the workpiece 116 may be an engine component, such as an engine block or a cylinder head.

The workpiece 116 may in particular have recesses or other scooping parts in which cleaning liquid can accumulate.

The workpiece 116 is introduced into the vacuum chamber 102 immediately after the cleaning operation. In particular, the workpiece 116 is not subjected to a blow-off process before it is introduced into the vacuum chamber 102. The usual predrying process in a blowing zone is thus dispensed with in the device 100 described here and the drying method carried out in order to avoid back-soiling through such a predrying process.

The movable between a loading position and a working position workpiece holder 112 forms a shuttle system by means of which the vacuum chamber 102 can be loaded with the workpiece 116 and by means of which the workpiece 116 can be discharged from the vacuum chamber 102 again. On a roller conveyor for loading and unloading the vacuum chamber 102 with the workpiece to be dried 116 can therefore be omitted. This offers the advantage that a small vacuum chamber 102 can be used and that no dirt pockets form which frequently occur when using a roller conveyor.

The workpiece holder 112 is brought into the loading position shown in solid lines in Fig. 1, in which the workpiece to be dried 116 is placed on the workpiece holder 112 and locked by means of the locking device 114 on the workpiece holder 112.

Subsequently, the workpiece holder 112 is moved from the loading position into the working position shown in broken lines in FIG. 1, wherein at the same time the access opening 108 of the vacuum chamber 102 is closed gas-tight by means of the lid 110.

The interior 118 of the vacuum chamber 102 is evacuated by the vacuum generator 138 to a final pressure in the range of about 30 mbar or less, preferably in the range of about 5 mbar or less.

Critical locations of the workpiece 116 that do not become dry by vacuum drying alone, for example, deep holes on the workpiece 116, are delivered by the blowing device 146 through the blowing nozzles 148 with short blowing medium pulses (having a duration of, for example, 1.0 second or less, preferably of about 0.5 sec or less).

The pressure of the blowing medium can thereby correspond to the atmospheric pressure or, when compressed air is used, be above the atmospheric pressure, preferably at least approximately 1 bar, in particular at least approximately 5 bar, above the atmospheric pressure. By acting on the workpiece 116 with the blowing medium pulses, cleaning liquid adhering to the workpiece 116, for example water, is distributed over a wide area on the workpiece surface. The heat energy stored in the workpiece 116 assists the subsequent vacuum drying process.

To perform the vacuum drying process, the pressure in the vacuum chamber 102 is maintained at the above-mentioned low final pressure for a predetermined period of time.

Also during the vacuum drying process, the workpiece 116 can be subjected to blowing medium pulses.

After the vacuum drying operation, the vacuum chamber 102 is vented.

For this purpose, the blow nozzles 148, which are directed onto the workpiece 116, are supplied with blowing medium, which has been guided via the fine filter 158.

The blowing medium used for aeration may be the same medium which has been used to produce the blowing medium pulses at the beginning of the drying process, or may be a different blowing medium.

In particular, ambient air or compressed air, preferably from a compressed air network, can be used for ventilating the interior 118 of the vacuum chamber 102.

Upon venting the interior 118 of the vacuum chamber 102 through the tuyeres 148, the supplied blowing medium expands upon entry into the vacuum chamber 102, thereby cooling the blowing medium and, in turn, cooling the workpiece 116 toward which the blowing media jets are directed upon aeration of the vacuum chamber 102. As a result of this cooling of the workpiece 116 within the vacuum chamber 102 during aeration thereof, the distance of the workpiece temperature from the room temperature is reduced so that a subsequent cooling process of the workpiece 116 inside or outside the vacuum chamber 102 can be shortened or completely eliminated.

By the combination of blowing off of the workpiece 116, vacuum drying of the workpiece 116 and cooling of the workpiece 116, all of which take place in the interior 118 of the vacuum chamber 102, a considerable shortening of the drying process is achieved. The drying process is very energy efficient and free of contamination.

In addition, with the device 100 according to the invention it is possible to use a vacuum pump 140 with lower power.

In a variant of the above-described embodiment of a device 100 for drying workpieces 116 after a cleaning process described above in FIGS. 1 and 2, the device 100 is further provided with a device (not shown) for rotating or tilting the vacuum chamber 102, with which 1 and 2, in which the longitudinal direction 132 of the vacuum chamber 102 is oriented substantially horizontally, the vacuum chamber 102 can be brought into an end position in which the longitudinal direction 132 of the vacuum chamber 102 is oriented substantially vertically.

In this case, the transfer of the vacuum chamber 102 from the starting position into the end position preferably takes place after the introduction of the workpiece 116 into the interior space 118 of the vacuum chamber 102 and before or during the execution of the vacuum drying process. Before the removal of the workpiece 116 from the interior 118 of the vacuum chamber 102, the vacuum chamber 102 is preferably moved back again from the end position to the starting position.

By moving the vacuum chamber 102 with the workpiece 116 disposed therein from the starting position to the end position, by an angle of, for example, about 90 °, scooping parts of the workpiece 116 (in particular recesses of the workpiece 116 filled with cleaning fluid), which at in the starting position located workpiece 116 still remain in the workpiece 116, drained, so that the accumulated in such lots cleaning liquid is removed from the workpiece 116.

Incidentally, this variant of a device 100 for drying workpieces 116 after a cleaning process in terms of construction and operation is the same as in the embodiment illustrated in FIGS. 1 and 2, to the above description of which reference is made.

A second embodiment of a device 100 for drying workpieces 116 after a cleaning process shown in FIGS. 3 and 4 differs from the first embodiment shown in FIGS. 1 and 2 in that the longitudinal direction 132 of the vacuum chamber 102, and thus in particular also the longitudinal central axis 136 of the vacuum chamber 102, not substantially horizontally, but substantially parallel to the vertical 180 is aligned.

This embodiment of the device 100 is particularly recommended if the cleaning liquid remaining in the workpiece 116 after the cleaning process can flow out of the workpiece 116 more easily when the workpiece 116, that is to say the vertically aligned longitudinal direction 182 of the workpiece 116, is stationary. In all other cases, the illustrated in FIGS. 1 and 2, the first embodiment of a device 100 is preferred in which the longitudinal direction 132 of the vacuum chamber 102 at least during the loading of the vacuum chamber 102 with the workpiece 116 is aligned substantially horizontally, since in this arrangement the handling of the workpiece 116 and its locking on the workpiece holder 112 are simpler.

Furthermore, the second embodiment of a device 100 shown in FIGS. 3 and 4 differs from the first embodiment in that the liquid discharge 176 in the second embodiment is not disposed on the peripheral wall of the main body 104 of the vacuum chamber 102, but instead at the top of the Closing portion 106 of the vacuum chamber 102 opens into the interior 118 of the vacuum chamber 102. It is thereby achieved that, even in the second embodiment, the liquid can be discharged from the lowest point of the vacuum chamber 102 through the liquid outlet 176 from the vacuum chamber 102.

In the second embodiment, however, the evacuation line 142 preferably opens into the interior 118 of the vacuum chamber 102 through the peripheral wall of the main body 104 of the vacuum chamber 102.

Characterized in that the inside of the lid 110 is concavely curved, it is achieved that the inner wall 164 of the vacuum chamber 102, in particular of the vertically disposed over the workpiece 116 located in the working position part of the inner wall 164, is curved, so that there is no Accumulate liquid and can fall down on the workpiece 116.

Incidentally, the second embodiment of a device 100 shown in FIGS. 3 and 4 for drying workpieces 116 after a cleaning process has the same structure and functionality as in FIG. 1 2 and 2, the above description of which is incorporated herein by reference.

In particular, in a variant of the second embodiment may also be provided that a device for rotating or tilting the vacuum chamber 102 is present, by means of which the vacuum chamber 102 from the starting position shown in Figs. 3 and 4, in which the longitudinal direction 132 of the vacuum chamber 102nd is oriented substantially vertically, can be brought into an end position in which the longitudinal direction 132 of the vacuum chamber 102 is oriented substantially horizontally. In this way, scooping parts of the workpiece 116, which still remain filled with cleaning fluid when the workpiece 116 is in the starting position, can be swiveled out during the rotation by, for example, approximately 90 °.

Claims

claims

A device for drying workpieces (116) after a cleaning process, comprising a vacuum chamber (102) for vacuum drying a workpiece (116) to be dried, characterized in that the device (100) comprises at least one tuyere (148) opening into the vacuum chamber (102) ), by means of which the workpiece to be dried (116) can be acted upon by a blowing medium.

2. Device according to claim 1, characterized in that the device (100) comprises a device for generating blowing medium pulses.

3. Device according to one of claims 1 or 2, characterized in that the vacuum chamber (102) by at least one blowing nozzle (148) is ventilated.

4. Device according to one of claims 1 to 3, characterized in that the device (100) comprises at least one fine filter (158) through which a blowing medium to at least one blowing nozzle (148) can be supplied st.

5. Device according to one of claims 1 to 4, characterized in that the device (100) comprises at least one opening in the vacuum chamber (102) cleaning nozzle (168).

Device according to one of claims 1 to 5, characterized in that the vacuum chamber (102) comprises at least one liquid outlet (176).

Device according to one of claims 1 to 6, characterized in that the free volume of the vacuum chamber (102) is at most 200% of the volume of the workpiece (116) occupied.

Device according to one of claims 1 to 7, characterized in that at least one part of an inner wall (164) of the vacuum chamber (102) arranged perpendicularly above the workpiece (116), which is located in a working position within the vacuum chamber (102), against the Horizontal (134) is inclined and / or curved.

Device according to one of claims 1 to 8, characterized in that the device (100) comprises a workpiece holder (112) which between a working position within the vacuum chamber (102) and a loading position in which the workpiece holder (112) at least partially outside of Vacuum chamber (102) is arranged, is movable.

Apparatus according to claim 9, characterized in that the device (100) comprises a lid (110) which is movable together with the workpiece holder (112) and closes an access opening (108) of the vacuum chamber (102) when the workpiece holder (112). is in their working position.

Device according to one of claims 1 to 10, characterized in that the vacuum chamber (102) has a longitudinal direction (132), which is aligned during the introduction of the workpiece to be dried (116) in the vacuum chamber (102) substantially horizontally.

12. Device according to one of claims 1 to 10, characterized in that the vacuum chamber (102) has a longitudinal direction (132) which is aligned during the introduction of the workpiece to be dried (116) in the vacuum chamber (102) substantially vertically.

13. Device according to one of claims 1 to 12, characterized in that the vacuum chamber (102) has a longitudinal direction (132) whose orientation is variable, in particular rotatable and / or tiltable, while the workpiece (116) within the vacuum chamber ( 102) is arranged.

14. A method for drying workpieces (116) after a cleaning process, comprising the following method steps:

Introducing a workpiece (116) to be dried into a vacuum chamber (102);

Applying a blowing medium to the workpiece within the vacuum chamber (102) through at least one tuyere (148);

Evacuating the vacuum chamber (102) to vacuum dry the workpiece (116);

Venting the vacuum chamber (102);

Discharging the workpiece (116) from the vacuum chamber (102).

15. The method according to claim 14, characterized in that the ventilation of the vacuum chamber (102) takes place with a venting gas, which is under a relation to the atmospheric pressure increased pressure.