WO2015165544A1 - Method of pumping in a pumping system and vacuum pump system - Google Patents

Abstract

The present invention relates to a method of pumping in a pumping system (SP, SPP) comprising: a primary lubricated vane screw vacuum pump (3) with a gas inlet opening (2) linked to a vacuum chamber (1) and a gas outlet opening (4) that opens into a conduit (5) before opening into the gas outlet (8) of the pumping system (SP, SPP), a check valve (6) positioned in the conduit (5) between the gas outlet opening (4) and the gas outlet (8), and an ejector (7) connected in parallel with the check valve (6). According to said method, the primary lubricated vane screw vacuum pump (3) is operated in order to pump the gases contained in the vacuum pump (1) through the gas outlet opening (4); simultaneously, the ejector (7) is supplied with motive medium, and the ejector (7) continues to be supplied with motive medium throughout the time that the primary lubricated vane vacuum pump (3) is pumping the gases contained in the vacuum chamber (1) and/or throughout the time that the primary lubricated vane vacuum pump (3) is maintaining a predefined pressure in the vacuum chamber (1). The present invention also relates to a pumping system (SP, SPP) suitable for being used for implementing said method.

Description

 Pumping method in a pumping system

 and vacuum pump system

Technical field of the invention

The present invention relates to a pumping method for reducing the electrical power consumption as well as the performance in terms of flow and final vacuum in a pumping system whose main pump is a lubricated vane vacuum pump.

Also, the present invention relates to a pumping system that can be used to perform the method according to the present invention.

Prior art

The general trends of increasing the performance of vacuum pumps, reducing plant costs and energy consumption in the industry have brought significant changes in terms of performance, energy savings, space requirements, in training, etc.

The state of the art shows that in order to improve the final vacuum and to reduce the energy consumption, it is necessary to add additional stages in the multi-stage Roots or multi-stage Claws vacuum pumps. For screw vacuum pumps it is necessary to put additional turns on the screws, and / or to increase the internal compression ratio. For vacuumed vane vacuum pumps, one or more stages must also be added

additional serial and increase the internal compression ratio.

The state of the art concerning pumping systems aimed at improving the final vacuum and increasing the flow rate shows Roots booster pumps arranged upstream of the lubricated vane primary pumps. This type of system is cumbersome, works either with by-pass valves having reliability problems, or by employing means of measurement, control, adjustment or control. However, these control means, adjustment or servo must be controlled in an active manner, which necessarily results in an increase in the number of components of the system, its complexity and its cost.

Summary of the invention

The object of the present invention is to propose a pumping method in a pumping system making it possible to reduce the electrical energy necessary for evacuating a vacuum chamber and maintaining the vacuum in this chamber, as well as for performing a lowering of the temperature of the exit gases.

Another object of the present invention is to propose a method of pumping in a pumping system making it possible to obtain a higher flow rate at low pressure than that which can be obtained by means of a vacuum pump with vanes lubricated alone during the pumping a vacuum chamber.

Another object of the present invention is to propose a pumping method in a pumping system which makes it possible to obtain a better vacuum than that which can be obtained by means of a vacuum vane pump lubricated alone in a vacuum chamber. .

These objects of the present invention are achieved by means of a pumping method which is carried out in the context of a pumping system whose configuration consists essentially of a lubricated vane primary vacuum pump provided with an orifice a gas inlet connected to a vacuum chamber and a gas outlet opening in a conduit which is provided with a check valve before opening into the atmosphere or other devices. The suction of an ejector is connected in parallel with the non-return valve, its outlet going to the atmosphere or joining the conduit of the primary pump after the non-return valve. Such a method of pumping is in particular the subject of independent claim 1. Different preferred embodiments of the invention are furthermore the subject of the dependent claims.

The method essentially consists in supplying the driving fluid and operating the ejector continuously all the time that the lubricated vacuum primary vacuum pump pumps the gases contained in the vacuum chamber by the gas inlet orifice, but Also, all the time that the lubricated vane primary vacuum pump maintains a defined pressure (eg the final vacuum) in the chamber by pushing back the gases through its outlet.

According to a first aspect, the invention resides in the fact that the coupling of the lubricated vanes primary vacuum pump and the ejector does not require specific measurements and devices (eg pressure sensors, temperature sensors, current, etc.), servocontrols or data and calculation management. Therefore, the pumping system adapted for the implementation of the pumping method according to the present invention comprises a minimum number of components, is very simple and costs significantly less than existing systems.

By its nature, the ejector built into the pumping system can still operate without damage according to this method of pumping. Its dimensioning is conditioned by a minimum motor fluid consumption for the operation of the device. It is normally single-storey. Its nominal flow rate is chosen according to the volume of the outlet duct of the lubricated vane primary vacuum pump, limited by the non-return valve. This flow rate may be 1/500 to 1/20 of the nominal flow rate of the lubricated vane primary vacuum pump, but may also be lower or higher than these values. The driving fluid for the ejector may be compressed air, but also other gases, for example nitrogen.

The non-return valve, placed in the conduit at the outlet of the lubricated vane primary vacuum pump, may be a standard commercially available element. It is dimensioned according to the rated flow rate of the lubricated vane primary vacuum pump. In particular, it is expected that the check valve return closes when the suction pressure of the lubricated vane primary vacuum pump is between 500 mbar absolute and the final vacuum (eg 100 mbar).

According to another variant, the ejector is multi-stage.

According to yet another variant, the ejector may be made of high chemical resistance material substances and gas commonly used in the chemical industry, that of semiconductors, both in the single-stage ejector variant as in that of the multi-stage ejector.

The ejector is preferably small.

According to another variant, the ejector is integrated in a cartridge which incorporates the non-return valve.

According to yet another variant, the ejector is integrated in a cartridge which incorporates the non-return valve and this cartridge itself is housed in the oil separator of the lubricated vane primary vacuum pump.

According to yet another variant of the method of the present invention, to meet specific requirements, the flow of gas at the pressure necessary for the operation of the ejector is controlled "all or nothing". Indeed, the control consists of measuring one or more parameters and putting the ejector into operation or stop it, according to certain predefined rules. The parameters, provided by suitable sensors, are p. ex. the motor current of the lubricated vane vacuum pump, the temperature or pressure of the gases in the volume of the outlet duct of the lubricated vane primary vacuum pump, limited by the check valve, or a combination of these parameters.

At the start of a drain cycle of the chamber, the pressure is high, for example equal to the atmospheric pressure. Due to the compression in the lubricated vane primary vacuum pump, the pressure of the gases discharged at its outlet is higher than the atmospheric pressure (if the gases at the outlet of the primary pump are discharged directly to the atmosphere) or higher than the pressure at the inlet of another device connected downstream. This causes the non-return valve to open.

When this check valve is open, the action of the ejector is very weakly felt, as the pressure at its entrance is almost equal to that of its output. On the other hand, when the check valve closes at a certain pressure (because the pressure in the chamber has meanwhile dropped), the action of the ejector causes a gradual reduction of the pressure difference between the chamber and the duct after the check valve. The pressure at the outlet of the lubricated vane primary vacuum pump becomes that at the inlet of the ejector, that of its outlet always being the pressure in the conduit after the non-return valve. The more the pump ejector, the higher the pressure at the outlet of the lubricated vane vacuum pump, in the closed volume (limited by the non-return valve) is reduced and therefore the pressure difference between the enclosure and the output of the vacuum pump with lubricated vanes lowered. This small difference reduces internal leakage in the lubricated vane vacuum pump and at the same time lowers the pressure in the enclosure, improving the final vacuum. In addition, the lubricated vane primary vacuum pump consumes less and less energy for compression and produces less and less compression heat.

In the case of control of the ejector, there is an initial position of starting the pump system when the sensors are in a defined state or give initial values. As the lubricated vane vacuum pump pumps the gases in the vacuum chamber, parameters such as its motor current, the temperature and the gas pressure in the volume of the outlet pipe begin to change. and reach threshold values detected by the sensors. This causes the ejector to start. When these parameters return to the initial ranges (out of setpoints) with a timer, the ejector is stopped.

According to yet another variant of the present invention, the flow of gas at the pressure necessary for the operation of the ejector is provided. by a compressor. Notably, this compressor can be driven by the lubricated vane primary pump or, alternatively or additionally, independently, independent of the lubricated vane primary pump. This compressor can draw atmospheric air or gases into the gas outlet duct after the non-return valve. The presence of such a compressor makes the lubricated vane vacuum pump systems independent of a source of compressed gas, which may meet certain industrial environments. The compressor can supply the gas flow at the pressure

necessary for the operation of several ejectors, respectively forming part of several vacuum pump systems with as primary pumps lubricated vane pumps. The compressor is part of the system both in the case of continuous operation of the ejector as in the case of its control according to the parameters, controlled by suitable sensors.

On the other hand, it is also obvious that the mechanical design study seeks to reduce the volume between the gas outlet of the lubricated vane primary vacuum pump and the non-return valve for the purpose of go down the pressure faster.

Brief description of the drawings

The features and advantages of the present invention will appear in more detail in the context of the description which follows with exemplary embodiments given by way of nonlimiting illustration with reference to the attached drawings which represent:

- Figure 1 schematically shows a pumping system adapted for carrying out a pumping method according to a first embodiment of the present invention; and

- Figure 2 schematically shows a pumping system adapted for the realization of a pumping method according to a second embodiment of the present invention. - Figure 3 schematically shows a pumping system adapted for the realization of a pumping method according to a third embodiment of the present invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS OF THE INVENTION

Figure 1 shows a pump system SP adapted for the implementation of a pumping method according to a first embodiment of the present invention.

This pumping system SP comprises an enclosure 1, which is connected to the suction port 2 of a lubricated vane primary vacuum pump 3. The gas outlet port of the lubricated vane primary vacuum pump 3 is connected to the conduit 5. A discharge check valve 6 is placed in the conduit 5, which after this non-return valve 6 continues in the gas outlet conduit 8. The non-return valve 6, when closed , allows the formation of a volume 4, between the gas outlet port of the primary vacuum pump 3 and itself. The pumping system SP also comprises an ejector 7, connected in parallel with the non-return valve 6. The suction orifice of the ejector is connected to the volume 4 of the conduit 5 and its discharge orifice is connected to the conduit 8. The supply duct 9 provides the driving fluid for the ejector 7.

As soon as the lubricated vane primary vacuum pump 3 is put into operation, the driving fluid for the ejector 7 is injected through the feed duct 9. Then, the lubricated vane primary vacuum pump 3 sucks the gases in the pump. 1 enclosure through the conduit 2 connected to its inlet and compresses them to discharge thereafter at its outlet in the conduit 5 by the non-return valve 6. When the closing pressure of the non-return valve 6 is reached, it closes. From this moment the pumping of the ejector 7 gradually lowers the pressure in the volume 4 to the value of its limit pressure. In parallel, the power consumed by the lubricated vane primary vacuum pump 3 gradually decreases. This occurs in a short period of time, for example for a certain cycle in 5 to 10 seconds. With a judicious adjustment of the flow of the ejector 7 and the closing pressure of the non-return valve 6 as a function of the flow rate of the lubricated vane vacuum pump 3 and the volume of the chamber 1, it is also it is possible to reduce the time before closing the non-return valve 6 with respect to the duration of the emptying cycle and thus reduce the losses of engine fluid during this operating time of the ejector 7 without effect on the pumping. Moreover, these "losses" which are minute, are taken into account in the balance of energy consumption. On the other hand, the advantage of simplicity credits an excellent reliability of the system as well as a lower price in comparison with similar pumps equipped with automaton

programmable and / or dimmer, pilot operated valves, sensors, etc.

FIG. 2 represents a pumping system SP adapted for the implementation of a pumping method according to a second embodiment of the present invention.

With respect to the system shown in FIG. 1, the system represented in FIG. 2 furthermore comprises a compressor 10 which supplies the gas flow rate at the pressure necessary for the operation of the ejector 7. Indeed, this compressor 10 can aspire atmospheric air or gases in the gas outlet duct 8 after the non-return valve 6. Its presence makes the pumping system independent of a source of compressed gas, which can meet certain industrial environments. The compressor 10 can be driven by the lubricated vane primary pump 3 or by its own electric motor, so completely independently of the pump 3. In all cases the energy consumption of the compressor 10 when it provides the flow rate of gas at the pressure needed to make

operate the ejector 7 is much smaller compared to the gain on the energy consumption of the main pump 3.

Figure 3 shows a vacuum pump system SPP adapted for implementing a pumping method according to a third embodiment of the present invention. With respect to the systems shown in FIGS. 1 and 2, the system represented in FIG. 3 corresponds to a controlled pumping system, which furthermore comprises sensors 1 1, 12, 13 which control p. ex. the motor current (sensor 1 1) of the lubricated vane primary vacuum pump 3, the pressure (sensor 13) of the gases in the volume of the outlet duct of the lubricated vane primary vacuum pump (limited by the check valve) 6), the temperature (sensor 12) of the gases in the volume of the outlet duct of the lubricated vane primary vacuum pump (limited by the non-return valve 6) or a combination of these parameters. In fact, when the lubricated vane primary vacuum pump 3 starts to pump the gases from the vacuum chamber 1, these mentioned parameters (in particular the current of its engine, the temperature and the pressure of the gases in the volume of the duct output 4) begin to change and reach threshold values detected by the corresponding sensors 1 1, 12, 13. This causes the ejector 7 to turn on (after a certain time delay). When these parameters return to initial ranges (out of setpoints) the ejector is stopped (again after a certain delay). Of course, the SSP driven pumping system may have as compressed gas source a distribution network or a compressor 10 under the conditions described in FIG. 2.

Certainly, the present invention is subject to many variations as to its implementation. Although various embodiments have been described, it is well understood that it is not conceivable to exhaustively identify all possible modes. It is of course conceivable to replace a means described by equivalent means without departing from the scope of the present invention. All these modifications are part of the common knowledge of a person skilled in the field of vacuum technology.

Claims

claims

1. Pumping method in a pumping system (SP, SPP) comprising:

- a lubricated vane primary vacuum pump (3) with a gas inlet port (2) connected to a vacuum chamber (1) and a gas outlet port (4) in a front conduit (5) to open into the gas outlet (8) of the pumping system (SP, SPP),

a non-return valve (6) positioned in the duct (5) between the gas outlet (4) and the gas outlet (8), and

- an ejector (7) connected in parallel with the non-return valve (6), the method being characterized in that the lubricated vane primary vacuum pump (3) is started in order to pump the gases contained in the enclosure empty (1) through the gas outlet (4); simultaneously, the ejector (7) is supplied with motor fluid; and the ejector (7) continues to be supplied with motor fluid all the time that the lubricated vane primary vacuum pump (3) pumps the gases contained in the vacuum chamber (1) and / or all the time that the lubricated vane primary vacuum pump (3) maintains a defined pressure in the vacuum chamber (1).

2. Pumping method according to claim 1, characterized in that the outlet of the ejector (7) joins the conduit (5) after the non-return valve (6).

3. A pumping method according to claim 1 or 2, characterized in that the ejector (7) is dimensioned to have a minimum motor fluid consumption.

Pumping method according to one of Claims 1 to 3, characterized in that the nominal flow rate of the ejector (7) is chosen as a function of the volume of the outlet pipe (5) of the primary vacuum pump. lubricated pallets (3) which is limited by the non-return valve (6).

5. Pumping method according to claim 4, characterized in that the flow of the ejector is 1/500 to 1/20 of the nominal flow rate of the lubricated vane primary vacuum pump (3).

6. Pumping method according to any one of claims 1 to 5, characterized in that the driving fluid of the ejector (7) is compressed air and / or nitrogen.

7. Pump method according to any one of claims 1 to 6, characterized in that the ejector (7) is single-stage or multi-stage.

Pumping method according to one of Claims 1 to 7, characterized in that the non-return valve (6) closes when the suction pressure of the lubricated vane primary vacuum pump (3) is reached. is between 500 mbar absolute and the final vacuum.

Pumping method according to one of claims 1 to 8, characterized in that the ejector (7) is made of a material with high chemical resistance to substances and gases commonly used in the chemical industry and / or semiconductor industry.

10. Pumping method according to any one of

Claims 1 to 9, characterized in that the ejector (7) is integrated in a cartridge which incorporates the non-return valve (6).

1 1. Pumping method according to claim 10, characterized in that the cartridge itself is housed in the oil separator of the lubricated vane primary vacuum pump.

12. Pumping method according to any one of

Claims 1 to 1 1, characterized in that the gas flow rate at the pressure necessary for the operation of the ejector (7) is provided by a

compressor (10).

Pumping method according to claim 12, characterized in that the compressor (10) is driven by the lubricated vane primary pump (3).

Pumping method according to claim 12, characterized in that the compressor (10) is driven independently, independent of the lubricated vane primary pump (3).

15. Pumping method according to any one of

Claims 12 to 14, characterized in that the compressor (10) draws atmospheric air or gases into the gas outlet duct (8) after the non-return valve (6).

16. Pumping method according to any one of

Claims 1 to 15, characterized in that at least one operating parameter is measured and used to start or stop the ejector (7).

Pumping method according to claim 16, characterized in that the at least one operating parameter is the motor current of the lubricated vane vacuum pump 3, the pressure of the gases in the volume of the outlet pipe of the pump. characterized by the non-return valve 6, the temperature of the gases in the volume of the outlet duct of the lubricated vane vacuum pump limited by the non-return valve 6 or a combination of these parameters.

18. A pumping system (SP, SPP) comprising:

- a lubricated vane primary vacuum pump (3) with a gas inlet port (2) connected to a vacuum chamber (1) and a gas outlet port (4) in a front conduit (5) to exit into the gas outlet (8) of the vacuum pump system (SP),

a non-return valve (6) positioned in the duct (5) between the gas outlet (4) and the gas outlet (8), and

- an ejector (7) connected in parallel with the non-return valve (6), the pumping system (SP, SPP) being characterized in that the ejector (7) is arranged to be able to be supplied with motor fluid all the time the lubricated vane primary vacuum pump (3) pumps the gases contained in the vacuum vessel (1) and / or the entire time that the lubricated vane primary vacuum pump (3) maintains a defined pressure in the vacuum enclosure (1).

Pumping system according to claim 18, characterized in that the outlet of the ejector (7) joins the duct (5) after the non-return valve (6).

20. Pump system according to claim 18 or 19, characterized in that the ejector (7) is dimensioned to have a minimum motor fluid consumption.

21. Pumping system according to one of Claims 18 to 20, characterized in that the nominal flow rate of the ejector (7) is chosen as a function of the volume of the outlet duct (5) of the lubricated vane primary vacuum pump. (3) which is limited by the non-return valve (6).

22. Pumping system according to claim 21, characterized in that the flow of the ejector is 1/500 to 1/20 of the nominal flow rate of the lubricated vane primary vacuum pump (3).

23. Pumping system according to any one of claims 18 to 22, characterized in that the driving fluid of the ejector (7) is compressed air and / or nitrogen.

24. Pump system according to any one of claims 18 to 23, characterized in that the ejector (7) is single-stage or multi-stage.

Pumping system according to one of Claims 18 to 24, characterized in that the non-return valve (6) closes when the suction pressure of the lubricated vane primary vacuum pump (3) is reached. is between 500 mbar absolute and the final vacuum.

26. Pumping system according to any one of claims 18 to 25, characterized in that the ejector (7) is made of material with high chemical resistance to substances and gas commonly in the chemical industry and / or industry semiconductors.

27. Pumping system according to any one of claims 18 to 26, characterized in that the ejector (7) is integrated in a cartridge which incorporates the non-return valve (6).

28. Pumping system according to claim 27, characterized in that the cartridge itself is housed in the oil separator of the lubricated vanes vacuum primary pump.

Pumping system according to one of claims 18 to 28, characterized in that the system comprises a compressor (1) which supplies the gas flow rate at the pressure necessary for the operation of the ejector (7).

Pumping system according to Claim 29, characterized in that the compressor (10) is driven by the lubricated vane primary pump (3).

31. Pumping system according to claim 29, characterized in that the compressor (10) is independently driven independently of the lubricated vane primary pump (3).

Pumping system according to one of claims 29 to 31, characterized in that the compressor (10) draws atmospheric air or gases into the gas outlet pipe (8) after the non-return valve ( 6).

33. Pumping system according to any one of claims 18 to 32, characterized in that it comprises at least one sensor (1 1, 12, 13) for measuring at least one operating parameter and for using it to put operating or stopping the ejector (7).

34. Pumping system according to claim 34, characterized in that the at least one operating parameter is the motor current of the lubricated vane vacuum pump 3, the pressure of the gases in the volume of the outlet pipe of the pump. characterized by the non-return valve 6, the temperature of the gases in the volume of the outlet duct of the lubricated vane vacuum pump limited by the non-return valve 6 or a combination of these parameters.