EP1020388A2 - Air passage switching and/or air control device - Google Patents

Abstract

Between the air pressure source and the ejector (3) is a shiftable shut-off valve (2) which can be controlled to switch on and off alternately in the beat of the sheet-processing machine. The timings of the switching on and off within one work beat can be adjusted in dependence on the production data. An adjustable throttle element can be provided between the air pressure and ejector through which the flow volume flowing through the throttle can be adjusted. The shut off valve and/or throttle element can be adjusted manually.

Description

The invention relates to an air control and / or air control device for air consumers on sheet-processing machines, in particular Sheet feeders, with an air pressure source, of which an overpressure air flow can be generated and processed in time with the bow Machine an inlet of small cross section of an ejector can be fed and through the ejector to an outlet of large cross section of the ejector flows, being between the inlet and outlet of the ejector radial connection opens into the ejector and the outlet or the radial Connection of the ejector is connected to the air consumer.

With such air control and / or air regulation devices, it is known to the radial connection of the ejector as a vacuum consumer To connect the suction of a sheet feeder. Because at the radial connection of the ejector creates a negative pressure when air flows through it vacuum is applied to the vacuum cleaner.

The largely uniform performance of the pump leads to the same length Times until the desired vacuum is built up on the suction cups, what with different operating conditions at different reaction times the air consumer and thus a disrupted operational process leads.

The object of the invention is therefore an air control and / or air control device of the kind mentioned in the beginning to create that simple is and a fast, adapted to the respective operating conditions Allows air consumers to respond.

This object is achieved in that between the Air pressure source and the ejector a switchable check valve arranged is that alternately up and down in time with the sheet processing machine can be activated, the time or times of opening and closing Activation within one work cycle depending on production data is adjustable.

In another embodiment, the object is achieved in that between the air pressure source and the ejector an adjustable throttle element is arranged through which the flow through the throttle element Volume flow is adjustable depending on production data. In order to become the operating procedures of the air pressure consumers in a simple manner optimally matched to the respective operating conditions.

The check valve and / or the throttle element can be manually dependent the production data or automatically depending on production data recorded by sensors can be adjustable.

The production data can process the machine speed of the sheets Machine and / or the type and quality of and / or the format sheet to be processed. Are e.g. the sheets to be processed of relatively high weight or of greater air permeability a higher suction power is required for a vacuum cleaner as an air consumer, in order to reliably capture the sheet to be captured. To make sure Capture at the right time and don't be late to let, the switchable valve compared to normal operation prematurely opened or the flow resistance of the throttle element be reduced so that the required suction power at the optimal time is fully built.

If the shut-off valve is activated during one turn the drive of the sheet processing machine defined work cycle at a higher machine speed to an earlier angular position of the drive than at a lower machine speed, so takes place opposite a normal operation leading an opening of the check valve, so that a larger angular range of the drive and therefore a longer time for Is available during which the suction pressure can be built up. This means that the full suction power is available at the optimal time.

To be able to generate an increased vacuum, several Ejectors with cross sections tapering in the direction of flow be arranged one behind the other, the individual radial connections merged into a common radial connection are.

One embodiment of the invention is that the radial connection of the ejector leads to a vacuum consumer and the outlet of the ejector forms an outlet of the air flow leading to the atmosphere.

So that there are no disturbing noises at the outlet of the ejector, the outlet can be connected to the atmosphere via a silencer his.

If the connection leads to a plurality of vacuum consumers, then only little effort to supply several vacuum consumers required.

Another air control and / or air control device that also requires little effort is that the airflow from the air pressure source can be fed to the inlets of a plurality of ejectors.

The vacuum consumer can be a suction device, in particular a lifting suction device or be a vacuum cleaner.

Is a controllable between ejector and vacuum consumer Quick exhaust valve arranged through which preferably a connection can be opened from the air pressure source to the vacuum consumer, so a quick vacuum reduction and thus a quick release of the sheets from a suction cup.

Another embodiment of the invention is that the radial Connection of the ejector is connected to the outside air and the Outlet of the ejector leads to a blown air consumer. With this configuration the negative pressure becomes the narrowest point of the ejector exploited, the outside air via the junction there is sucked in, so that at the outlet of the ejector opposite to that of air flow supplied to the pressure pump increased air volume flow is available to the blown air consumer with low Pressure and lower flow rate is supplied. In order to the air pressure source can be designed with a smaller capacity. In a simple manner, the outlet of the ejector can be a plurality of Blown air consumers or the air flow from the air pressure source Inlets can be fed to a plurality of ejectors.

A particularly simple embodiment results when the outlet of the Ejector forms the blown air consumer.

The blown air consumer can use a blower nozzle, in particular a separating blower nozzle or a pre-loosening blow nozzle.

Is multiple ejectors a switchable check valve or a throttle element upstream, each ejector can do this individually controlled and clocked and, if necessary, the control and the clock individually to be changed.

Particularly short flow paths and thus short air control times can can be achieved in that ejector and switchable valve or Throttle element and, if applicable, vacuum or blown air consumers, one structural unit form. This enables the cycle times of the sheets to be shortened processing machine.

Is the switchable check valve a 2/2-way valve, in one position the ejector with the air pressure source and in its other position the Ejector is connected to the atmosphere, so takes place in one position of the 2/2-way valve an overpressure or underpressurization of the Air consumer and in the other position an exposure to the Air consumer with atmospheric pressure, what with vacuum consumers means an immediate breakdown of the vacuum.

In order to achieve high switching speeds and therefore short air control times, the switchable shut-off valve can be a solenoid valve.

The air pressure source can be a compressed air pump or a compressed air reservoir his.

Figur 1

ein Schaltbild eines ersten Ausführungsbeispiels mit unterdruckbeaufschlagbaren Luftverbrauchern

Figur 2

ein Schaltbild eines zweiten Ausführungsbeispiels mit unterdruckbeaufschlagbaren Luftverbrauchern

Figur 3

ein Schaltbild eines dritten Ausführungsbeispiels mit unterdruckbeaufschlagbaren Luftverbrauchern

Figur 4

ein Schaltbild eines vierten Ausführungsbeispiels mit unterdruckbeaufschlagbaren Luftverbrauchern

Figur 5

ein Schaltbild eines ersten Ausführungsbeispiels mit überdruckbeaufschlagbaren Verbrauchern

Figur 6

ein Schaltbild eines zweiten Ausführungsbeispiels mit überdruckbeaufschlagbaren Verbrauchern

Figur 7

ein Schaltbild eines dritten Ausführungsbeispiels mit überdruckbeaufschlagbaren Verbrauchern.

Embodiments of the invention are shown in the drawing and are described in more detail below. Show it

Figure 1

a circuit diagram of a first embodiment with air consumers that can be subjected to vacuum

Figure 2

a circuit diagram of a second embodiment with pressurizable air consumers

Figure 3

a circuit diagram of a third embodiment with negative pressure air consumers

Figure 4

a circuit diagram of a fourth embodiment with air consumers that can be subjected to vacuum

Figure 5

a circuit diagram of a first embodiment with consumers that can be pressurized

Figure 6

a circuit diagram of a second embodiment with consumers that can be pressurized

Figure 7

a circuit diagram of a third embodiment with consumers that can be pressurized.

The embodiments shown in the figures have a Compressed air pump 1 trained air pressure source, from which an overpressure air flow via a in Figures 1-3 and 5-7 as a solenoid valve trained 2/2-way valve 2 and in Figure 4 designed as a solenoid valve Switching valve 2 'can be fed to one or more ejectors 3. The pressurized air flow is fed to the inlet 4 of the ejector 3.

When the 2/2-way valve 2 or switching valve 2 'is energized, the compressed air pump is 1 connected to the inlet 4 of the ejector 3, while when de-energized 2/2-way valve 2 or switching valve 2 'the inlet 4 of the ejector 3 communicates with the outside air.

In the transition area 6 which passes from the inlet 4 to the outlet 5 of the ejector 3, a connection 7 opens radially.

In Figures 1 to 4, the connection 7 leads to one or more than Known suction cups 8 trained vacuum consumers.

In the exemplary embodiment in FIG. 1, the connection 7 of the ejector 3 via branched lines 9 with three lifting suction units forming a group 8 connected so that they can be acted upon with negative pressure at the same time are.

The outlet 5 of the ejector 3 leads to a noise damper 10 The atmosphere.

The embodiment shown in Figure 2 already has in the feed line 11 of the 2/2-way valve 2 branches 20, each one Guide ejector 3 so that each vacuum cleaner 8 by its own ejector 3rd is supplied with negative pressure.

3 shows a feed line 12 coming from the compressed air pump 1, each branch 13 leads to a 2/2-way valve 2, the together with an ejector 3 and a lifting vacuum 8 each have a structural unit forms. Each suction cup 8 can thus be controlled individually.

In the embodiment in Figure 4, the basic structure of the embodiment 1 corresponds to the ejector 3 by a Bypass line 22 bypassed in which a controllable quick exhaust valve 23 is arranged. Should the bow lifted by the suction cups 8 can be released again from the suction cups 8, so the switching valve 2 'closed and the quick exhaust valve 23 opened so that the from the suction cups 8 gripped sheet can solve immediately.

Depending on the type of bow, the intensity of the suction cups 8 can be increased Bypass line 22 supplied positive pressure by a flow direction adjustable behind the quick exhaust valve 23 Throttle 24 can be set.

To prevent contamination from e.g. Paper dust in the via the switching valve 2 ' Avoiding air supplied to the ejector 3 is behind the ejector 3 Filter 25 arranged in line 9.

In Figures 5 to 7, the connection 7 leads to the outside air, during the Outlet 5 leads to one or more blown air consumers.

There is a branched supply line to the outlet 5 of the ejector 3 in FIG 14 connected, each branch 21 to one as a Btas nozzle 15 trained blown air consumer leads.

In the exemplary embodiment in FIG. 6, this is at the outlet of the 2/2-way valve 2 connected supply lines 16 are already branched, each branch 19 leading to the inlet 4 of an ejector 3, the Outlet 5 is simultaneously designed as a blowing nozzle 15.

Just like in FIG. 3, one coming from the compressed air pump 1 is shown in FIG Supply line 17 branches and each branch 18 a 2/2-way valve 2 supplied, which together with an ejector 3 and one Blower nozzle 15 forms a structural unit. This means that each blowing nozzle 15 is also here individually controllable.

It is understood that in an advantageous training, a combination the versions described in Figures 1 to 4 with those in the figures 5 to 7 described designs is possible by connecting 7 of an ejector 3 one or more suction air consumers and on the outlet 5 of the ejector 3 one or more blown air consumers connected are.

In all of the exemplary embodiments, activation of the 2/2-way valve or the switching valve 2 'the time and the duration of the Loading of the ejector (s) 3 with compressed air depending on production data, e.g. detected by sensors or manually in a control unit can be entered. Important production data are e.g. the speed of the drive of the sheet processing machine, the type and quality and the format of the sheets to be processed.

This can influence the workflow of air consumers Production data in its negative impact can be eliminated.

Reference list

1

Air pump

2nd

2/2 way valve

2 '

Switching valve

3rd

Ejector

4th

Inlet

5

Outlet

6

Transition area

7

Connection

8th

Suction cups

9

cables

10th

Silencer

11

Supply

12th

Supply

13

branch

14

Supply

15

Blow nozzle

16

Supply

17th

Supply

18th

branch

19th

branch

20th

Ramifications

21

branch

22

Bypass line

23

Quick exhaust valve

24th

throttle

25th

filter

Claims (27)

Air control and / or air control device for air consumers on sheet-processing machines, in particular sheet feeders, with an air pressure source from which an overpressure air flow can be generated and can be fed to the inlet of a small cross-section of an ejector in time with the sheet-processing machine and large through the ejector to an outlet Cross-section of the ejector flows, a radial connection opening into the ejector between the inlet and outlet of the ejector and the outlet or the radial connection of the ejector being connected to the air consumer, characterized in that a switchable shut-off valve is located between the air pressure source and the ejector (3) is arranged, which can be alternately activated and activated in time with the sheet-processing machine, the time or times of activation and activation within a work cycle being adjustable as a function of production data. Air control and / or air control device according to the preamble of claim 1, characterized in that an adjustable throttle element is arranged between the air pressure source and the ejector, by means of which the volume flow flowing through the throttle element can be set as a function of production data. Air control and / or air control device according to one of claims 1 and 2, characterized in that the check valve and / or the throttle element is manually adjustable depending on the production data. Air control and / or air control device according to one of claims 1 and 2, characterized in that the check valve and / or the throttle element can be set automatically as a function of production data detected by sensors. Air control and / or air control device according to one of the preceding claims, characterized in that the production data are the machine speed of the sheet processing machine and / or the type and quality and / or the format of the sheets to be processed Air control and / or air control device according to claim 5, characterized in that the activation of the check valve takes place during an operating cycle defined by one revolution of the drive of the sheet processing machine at a higher machine speed to an earlier angular position of the drive than at a lower machine speed. Air control and / or air control device according to one of the preceding claims, characterized in that a plurality of ejectors (3) with passage cross-sections increasing in the flow direction are arranged one behind the other, the individual radial connections of which are brought together to form a common radial connection. Air control and / or air regulation device according to one of the preceding claims, characterized in that the radial (7) connection of the ejector (3) leads to a vacuum consumer and the outlet of the ejector (3) forms an outlet (5) of the air flow leading to the atmosphere . Air control and / or air control device according to claim 8, characterized in that the connection (5) is connected to the atmosphere via a noise damper (10). Air control and / or air control device according to claim 8, characterized in that the connection (7) leads to a plurality of vacuum consumers. Air control and / or air regulation device according to claim 8, characterized in that the air flow of the air pressure source can be fed to the inlets (4) of a plurality of ejectors (3). Air control and / or air control device according to one of the preceding claims, characterized in that the vacuum consumer is a sucker. Air control and / or air control device according to claim 12, characterized in that the suction device is a lifting suction device (8) or a drag suction device. Air control and / or air control device according to one of the preceding claims, characterized in that a controllable quick exhaust valve (23) is arranged between the ejector (3) and the vacuum consumer. Air control and / or air regulation device according to claim 14, characterized in that a connection (22) from the air pressure source to the vacuum consumer can be opened by the quick exhaust valve (23). Air control and / or air control device according to one of the preceding claims 1-7, characterized in that the radial connection (7) of the ejector (3) is connected to the outside air and the outlet (5) of the ejector (3) leads to a blown air consumer . Air control and / or air control device according to claim 16, characterized in that the outlet of the ejector (3) leads to a plurality of blown air consumers. Air control and / or air regulation device according to claim 16, characterized in that the air flow of the air pressure source can be fed to the inlets (4) of a plurality of ejectors (3). Air control and / or air control device according to one of claims 16 to 18, characterized in that the outlet (5) of the ejector (3) forms the blown air consumer. Air control and / or air control device according to one of claims 16 to 19, characterized in that the blown air consumer is a blower nozzle (15). Air control and / or air control device according to claim 11, characterized in that the blowing nozzle (15) is a separating blowing nozzle or a pre-loosening blowing nozzle. Air control and / or air control device according to one of the preceding claims, characterized in that a switchable shut-off valve or a throttle element is connected upstream of several ejectors (3). Air control and / or air control device according to claim 22, characterized in that the ejector (3) and switchable shut-off valve or a throttle element and, if appropriate, vacuum or blown air consumers form a structural unit. Air control and / or air control device according to one of claims 22 to 23, characterized in that the switchable check valve is a 2/2-way valve (2), in one position the ejector (3) with the air pressure source and in its other position the Ejector (3) is connected to the atmosphere. Air control and / or air control device according to one of claims 22 to 24, characterized in that the switchable check valve is a solenoid valve. Air control and / or air control device according to one of the preceding claims, characterized in that the air pressure source is a compressed air pump (1). Air control and / or air control device according to one of claims 1 to 17, characterized in that the air pressure source is a compressed air reservoir.

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