DE10250532B3 - Propellant powered ejector assembly - Google Patents

Abstract

Propellant gas operated ejector with at least one primary nozzle line (12) with a driver nozzle (36) with a cross-sectional constriction and an adjoining receiver nozzle (32) as well as a suction line (24) opening into the constriction, characterized in that at least one switchable secondary nozzle line (14 ) is provided with a driver nozzle (38) having a cross-sectional constriction and an adjoining receiver nozzle (34), the constriction of the secondary nozzle branch (14) being connected to a suction line (24) when the secondary nozzle branch (14) is switched on and the at least one Secondary nozzle train (14) is preceded by a closure member (20) in the flow direction of the propellant gas, which switches the secondary nozzle train (14) on or off depending on the inlet pressure of the propellant gas into the ejector (10).

Description

The invention relates to a propellant gas operated ejector arrangement with the features of the preamble of Claim 1.

Such ejector arrangements or Jet pumps are known and work according to the Venturi principle. The filtered and lubricant-free compressed gas flows over you Connection piece and a propellant gas line in the ejector and gets into the propellant nozzle, where the flow velocity in the constriction the z. B. is used as propellant compressed air to supersonic speed. To the exit from the propellant nozzle expands the air and flows into a diffuser and from there, possibly via a silencer Free. This creates a vacuum in a chamber surrounding the motive nozzle, that leads to that air over a suction line that opens into the chamber is sucked in. The sucked in Air and the propellant gas introduced into the ejector pass together through the Expansion section out into the open.

Such jet vacuum pumps have across from Other vacuum pumps have the advantage that they have no rotating parts possess and are therefore low maintenance and wear. They are also explosion-proof because they work purely pneumatic. They also have a simple one Construction on and can be installed in any position. You develop no warmth and can can be switched on or off at any time so that energy is saved can be. Furthermore, the vacuum can be reduced due to short line lengths For example, a suction cup and the ejector can be set up quickly. Finally play the compact design, the low weight and the possibility multiple functions in one device summarize, with savings in the areas of construction, work preparation, purchasing, mechanical processing, assembly, commissioning and spare parts supply Roll.

From the DE 100 33 212 C1 a vacuum generating device is known which has a main suction nozzle unit with an upstream shut-off valve and an additional suction nozzle unit connected in parallel with the main suction nozzle unit. While the pressure medium supply to the main suction nozzle unit is controlled depending on the negative pressure generated by controlling a shut-off valve, the additional suction nozzle unit remains in operation.

The invention has for its object a Propellant powered ejector assembly to provide the desired suction power delivers in a simple manner, with a high and good suction power guaranteed on the other hand, the propellant gas consumption should be kept low should.

The object is achieved with a propellant operated ejector arrangement solved, having the features of claim 1.

According to the invention, it can thus be provided that, for example, the second nozzle train, namely the secondary nozzle line is only switched on when there is a high inlet pressure. The second Venturi nozzle is then activated and the result is such a very high pumping speed with high negative pressure. In this case, both Venturi nozzles work their pumping speed together, for example to feed a suction pad evacuate. Since the second Venturi nozzle is only activated when necessary will not become unnecessary Propellant gas consumed. In this way the modular connection one or more additional Venturi nozzle the suction power can be adjusted individually, in both cases a sufficient flow rate is achieved, both at high and at low required Suction power to ensure that always the evacuation process done safely can be.

Alternatively, it can also be provided that that at an inlet pressure below a certain switching pressure the secondary nozzle line is switched on, that is only at low inlet pressures both Nozzle strands use find and at high inlet pressures just about a nozzle train, namely the primary nozzle train is evacuated.

It can be provided according to a first embodiment, that the closure member by a biasing force in a first Position is held and the biasing force the input pressure of the propellant counteracts.

As a closure member, for example a bistable 2/2-way valve come into question. In these cases is the preload force by a spring, for example acts a piston provided. Depending on whether the secondary nozzle branch is switched on at low or high working pressures the first layer is as open or closed position defined. The check valve or closure member is regarding designed according to its switching direction. It can be provided that when the switching pressure is reached by the input pressure Closure member is transferred to a second position, where it is the second layer is the position of the closure member in which depending on the desired Switching direction of the secondary line contributes to the suction power or is switched off again.

It can also be provided here that the two nozzle strands have a common feed line in which the closure member engages is ordered. Compressed air is used as the propellant in most cases.

According to a further embodiment, be provided that the primary and the secondary nozzle line have a common suction line, it being in particular can be a continuous suction line by the two Crossed nozzle strands becomes. Between the secondary and the primary Nozzle train can here a check valve be arranged in the suction line, which is a leak from the first nozzle train generated vacuum prevented when the secondary nozzle line is switched off. Provided in the secondary nozzle line negative pressure is also generated, the check valve opens and the negative pressure of the secondary nozzle train also carries to the suction power in the suction line.

Alternatively, it can also be provided that that at least the secondary or another jet train or a group of nozzle strands each have their own separate suction line. This allows several Suction circles independent be switched on or off from each other.

The check valve can act in particular a spring-loaded ball valve, the spring forces can be set that even a small force is sufficient to overcome the spring force. In this case it can be provided that the check valve is already at a low suction power on the part of the secondary nozzle line. The minor Spring force is particularly sufficient because when the first is operated nozzle line against the shut-off ball due to the resulting negative pressure the locking seat pressed is, so that a leakage is already prevented relatively reliably becomes. If the spring force has only a low spring constant, can also operated two nozzle lines equipped with the same suction power be, since in this case the closure element is in a bistable Condition and the suction line for the second nozzle train open is.

In addition to the provision of a secondary nozzle train with the same suction power as the primary nozzle line can also be provided be that the secondary nozzle line has a different suction power than the primary nozzle train, in particular one greater suction power, for a complete and easy opening of the check valve sure. In particular, can be different about the providence Venturi nozzles different Type or performance classes the suction power, which in the Suction line and the suction nozzle is exercised, varied and allows such a safe setting of the required vacuum and the Evacuation time.

In addition to the provision of those previously described essentially two nozzle strands can too several primary and secondary nozzle strings connected in parallel are provided be, all primary Nozzle strands simultaneously are connected and all secondary Nozzle strands at be switched on or off at a uniform switching pressure. Furthermore can also be provided, in addition to the secondary, a tertiary or quaternary nozzle line to provide the other at another, in particular from the first switching pressure Switching pressure off or switches on, so that the suction power is further improved and regulated as required and can be controlled.

All Nozzle lines can be on be connected to a single suction line, in particular by the nozzle strands the Cross the suction line.

In particular, it can be provided that check valves only between strands different connection pressures are provided. This means, between different primary nozzle strands no check valves provided and there is only one check valve between one Group of primary nozzle strands and a group of secondary nozzle strands. Provided in addition to primary and secondary nozzle strands too Tertiary nozzle strands provided are, it can be provided that both between the primary and the secondary and the tertiary nozzle train check valve is arranged.

All Components and nozzle strands of the ejector can be arranged within a common housing. It can it should be provided that the housing z. B. from a block of material exists in which all Lines are introduced as bores and the nozzles and valves as stakes inserted into the block and fixed in it and surplus openings through Cover to be closed. This has special advantages maintenance or equipment or the exchange of individual components.

Other advantages and features of Invention result from the rest Documents. In the following drawing is a particularly preferred one embodiment described in detail.

Show:

1 2 shows a circuit diagram of an ejector according to the invention,

2 an exploded view of an ejector according to the invention and

3 a section through an ejector according to the invention.

1 shows a circuit diagram of an ejector or jet pump designated overall by 10. The ejector 10 comprises a primary nozzle train 12 and a secondary nozzle train 14 , The two nozzle strands are connected to a supply line 16 connected for a propellant gas, whereby according to the illustration 1 a common supply air duct 16 then for that Primary nozzle line 12 and for the secondary nozzle train 14 into the supply air lines 16 ' and 16 '' branched. The supply air line 16 ' for the primary nozzle train provides propellant gas for a first venturi arrangement 18 of the first nozzle line 12 , In the second supply air line 16 '' is a switching valve 20 arranged that the air either to the second venturi arrangement 22 of the second nozzle line 14 lets through or the supply air line 16 '' for the second arrangement 22 closes.

With the valve 20 is a bistable 2/2-way valve, which will be explained in more detail below.

Both the primary nozzle train 12 as well as the secondary nozzle train 14 stand with a suction line 24 connected, using a single suction line 24 the two nozzle strands 12 . 14 in the area of the respective cross-sectional constrictions in the Venturi arrangements 18 . 22 combines. Via the suction line 24 connected to a suction port 26 is connected, another line can be evacuated, for example, for a suction pad. In the suction line 24 is between the primary nozzle string 12 and the secondary nozzle train 14 a check valve 28 arranged, the leakage of the vacuum of the first nozzle train 12 prevented in the case of a secondary nozzle train that is not switched on. It is a spring-loaded ball valve.

The circuit according to 1 takes place so that the ejector 10 , as soon as it is supplied with propellant gas, here compressed air, at first only with regard to the primary nozzle train 12 is operated. The valve 20 is held in a locked position. The primary nozzle train 12 then creates a vacuum in the area of its cross-sectional constriction by accelerating the compressed air to supersonic speed in a chamber surrounding the constriction, through which the suction line 24 is evacuated. Through the check valve 28 the vacuum in the chamber is protected against leakage.

As soon as the supply pressure in the supply line 16 the compressed air a predetermined switching pressure for the valve 20 is reached, the second, namely secondary, nozzle train 14 switched on. At that moment the air consumption doubles, but so does the suction volume.

As soon as the inlet pressure is reduced, the valve switches 20 back into the locked position.

Here is a certain switching hysteresis of the valve 20 to consider.

The switching pressure is controlled by the valve 20 specified.

The structure is described below using an exploded view of an ejector according to the invention 10 are explained. The ejector 10 is in a case 29 housed and can by means of the housing 29 for example via attachment points 30 be fixed on a surface.

The two nozzle strands 12 and 14 consist essentially of a receiver nozzle 32 respectively 34 and a driver nozzle 36 respectively 38 connected to each other via an O-ring 40 are connected, and the the Venturi arrangements 18 . 22 form. Due to the narrowing of the cross-section in the driver nozzle 36 respectively 38 is about the supply line 16 injected compressed air accelerated to supersonic speed.

In the suction line 24 that the two nozzle strands 12 and 14 connects with each other and into a suction nozzle 26 flows, is between the two nozzle strands 12 and 14 a check valve 28 comprising a ball 42 as a closure body and a spring 44 arranged with a low spring constant. This creates the vacuum of the primary nozzle train 12 protected against leaks with respect to the secondary nozzle train.

The suction line 24 will be on both sides of the case 29 , through which it is drilled, with cover caps 46 , in particular closed plastic lid.

It can be provided in a particularly simplified manner that the housing 29 is not just a wrapping of the individual parts, but that the housing is a block of material in which the individual recesses for the supply line etc. such. B. the suction line and the intersecting compressed air lines of the nozzle strands 12 . 14 are milled in, with only the components such as driver and receiver nozzles and the valves being separate components which are pushed into the housing block and fixed there. In this way it can be achieved particularly easily; that the individual components or inserts are advantageously interchangeable. Such a jet pump can then be used 10 can be adapted to different types or performance classes in a few simple steps, without the entire jet pump 10 needs to be replaced. In addition, for example, the individual nozzles 32 - 38 easily removed for cleaning and / or inspection purposes, cleaned or examined and then reinstalled, whereby it can also be provided that individual parts can thereby be replaced particularly easily if they are defective, for example.

In addition, there is a 2/2-way valve in the area of the supply line 20 provided comprising a piston 48 which is an assembly with a piston seal 50 and an O-ring seal 52 forms. The piston is by a spring 54 , over whose spring constant and preload the switching point can be set, pressed in the direction of the spring longitudinal axis. The o-ring 52 seals the compressed air line of the secondary nozzle train 14 off when the piston 48 is arranged in a closed position, ie here its first position or rest position.

With her from the piston 48 the spring is on the opposite side 54 against a sealing plug 56 with which the preload of the spring can be adjusted.

With the valve closed 20 can use compressed air for the primary nozzle train 12 unobstructed on the switching piston 48 flow past. The switching piston has different cross sections over its length, the compressive forces of the inflowing compressed air over an annular surface with the larger cross section passing through an end face of the piston 48 is formed in the area of the larger cross-section on the piston 48 against the pressure direction of the spring 54 Act. The compressive forces are due to the circular surface 51 of the piston 48 , which can be influenced by the pressure forces.

Here is the piston 48 with its smaller cross-sectional area that with a corresponding smaller hole in the housing 28 corresponds, towards the second 14 Nozzles arranged.

If in the supply line 16 If there is compressed air, the piston 48 in terms of its area 51 pressurized. This force acts against the spring preload 54 , As soon as the force applied by the compressed air corresponds to the spring force due to increasing pressure and exceeds it, the piston becomes 48 against the spring force in the direction of the plug up to a designated stop. As a result, the feed line becomes the secondary nozzle train 14 released and the secondary nozzle train contributes to the suction power. This doubles the air consumption and the suction volume.

Is the supply pressure on the inlet line 16 is present, regulated back again, the piston moves 48 again in the direction of the second nozzle strand 14 in the supply air line 16 until the O-ring 52 the assembly consisting of a piston seal 50 , Piston 48 and o-ring 52 against the corresponding hole 53 and the associated surface in the housing block 29 rests and the piston 48 able on the cone surface 53 seals.

3 now shows the ejector 10 according to 2 in an assembled representation, here the position of the spring valve as a check valve 28 between the nozzle strands 12 and 14 can be seen.

The pressure forces of the compressed air act on the surface 51 , which has a ring shape. The spring force of the spring acts against these pressure forces, which are applied by the compressed air 54 , If the pressure forces exceed a switching pressure, the piston will 48 against the spring in the drawing 54 pressed and gives the passage to the second nozzle strand 14 free for the compressed air.

As soon as the second nozzle line also creates vacuum, the ball becomes 42 of the check valve against the spring force of the spring 44 due to the vacuum in the second nozzle line 14 towards the second nozzle line 14 moves and gives the passage in the suction line 24 free. It can then on the suction nozzle 26 an additional vacuum can be generated, for example for a suction cup. So that the check valve 28 is held in the release position, it is necessary that the suction power of the secondary suction line 14 the same size or larger than that of the primary line 12 is.

As soon as the pressure in the supply line 16 subsides and the piston 48 the feed to the second nozzle train 14 closes, due to the spring force of the spring 44 the ball 42 pressed back into the valve seat and closes the suction line 24 in the area of the narrowing of the first nozzle line 12 against leaks.

In this way, a second nozzle train can be switched on 14 only in those cases where increased suction power is required, and air can be saved in all other cases. The air consumption and suction power can be controlled efficiently.

Claims (14)

Propellant gas powered ejector assembly with at least one primary nozzle train ( 12 ) with a propellant nozzle with a cross-sectional constriction ( 36 ) and an adjoining receiver nozzle ( 32 ) and a suction line leading into the narrow point ( 24 ), whereby at least one switchable secondary nozzle train ( 14 ) is provided with a propellant nozzle with a cross-sectional constriction ( 38 ) and an adjoining receiver nozzle ( 34 ), the narrowest part of the secondary nozzle line ( 14 ) with a suction line ( 24 ) with activated secondary nozzle branch ( 14 ) is connected and the at least one secondary nozzle train ( 14 ) a closure organ ( 20 ) is connected upstream in the flow direction of the propellant gas, characterized in that the closure member ( 20 ) depending on the inlet pressure of the propellant gas into the ejector ( 10 ) the secondary nozzle train ( 14 ) switches on or off. Ejector arrangement according to claim 1, characterized in that the closure member ( 20 ) is held in a first position by a biasing force and the biasing force counteracts the input pressure of the propellant gas. Ejector arrangement according to claim 1 or 2, characterized in that the closure member ( 20 ) a piston ( 48 ) includes. Ejector arrangement according to claim 2 or 3, characterized in that the biasing force by a spring ( 54 ) on the piston ( 48 ) acts, is provided. Ejector arrangement according to one of the preceding existing claims, characterized in that when a switching pressure is reached by the input pressure of the propellant gas, the closure member ( 20 ) can be transferred to a second layer. Ejector arrangement according to claim 5, characterized in that at an inlet pressure lower than the switching pressure, the at least one secondary nozzle train ( 14 ) is switched off. Ejector arrangement according to claim 5, characterized in that at an inlet pressure greater than the switching pressure, the at least one secondary nozzle branch ( 14 ) is switched off. Ejector arrangement according to one of the preceding claims, characterized in that the two nozzle strands ( 12 . 14 ) a common LPG feed line ( 16 ) in which the closure member ( 20 ) is arranged. Ejector arrangement according to one of the preceding claims, characterized in that the nozzle strands ( 12 . 14 ) have a common suction line and that between the secondary nozzle line ( 14 ) and the primary nozzle train ( 12 ) a check valve ( 28 ) in the suction line ( 24 ) is arranged that there is a leakage from the first nozzle strand ( 12 ) vacuum generated when the secondary nozzle train is switched off ( 14 ) prevented. Ejector arrangement according to one of claims 1 to 8, characterized in that each nozzle train ( 12 . 14 ) or a group of nozzle lines a separate suction line ( 24 ) assigned. Ejector arrangement according to claim 9, characterized in that the check valve ( 28 ) is a spring-loaded ball valve. Ejector arrangement according to one of the preceding claims, characterized in that the secondary nozzle train ( 14 ) Same suction power as the primary nozzle train ( 12 ) having. Ejector arrangement according to one of claims 1 to 11, characterized in that the secondary nozzle train ( 14 ) a different suction power than the primary nozzle line ( 12 ), in particular has a higher suction power. Ejector arrangement according to one of the preceding claims, characterized in that a housing ( 29 ), with the lines bores in the housing ( 29 ) and the nozzles ( 32 - 38 ) and the valves ( 20 . 28 ) are kept interchangeable.