DE19625648A1 - Pump system - Google Patents

Abstract

Complex pressure programming of a fluid at a very high pressure is provided by a pumping system that employs a pneumatic amplifier pump (12) a pressure regulator (14A), and an electronic pressure control system (14). With electronic pressure control applied to a first fluid provided to the low pressure chamber of the pneumatic amplifier pump (12), the high pressure chamber of the pneumatic amplifier pump may be employed to provide a second fluid at a pressure suitable for use in solid phase extraction and in supercritical fluid applications such as supercritical fluid chromatography (SFC) and supercritical fluid extraction (SFE).

Description

The present invention relates to analyzers and especially on pump systems for use in analyzers ten.

High pressure fluids can be used as solvents in Ge advise on performing an extraction, a chromatograph phie and other related processes can be used. On such fluid has been characterized as a supercritical fluid s that as a hybrid mixture of a gas and a Liquid, which is a gas-like viscosity, a liquid density-like density and a diffusivity that is greater than that of a typical liquid solvent, is useful. The liquid-like density of a supercritical table fluids gives a variable, liquid-like Solvency, which is essentially a linear function of density over significant ranges of density. This allows the solvency, which is usually called a chemical interaction is considered simply by the setting of a physical parameter, namely the Density or pressure.

Supercritical fluids are used for extraction complex matrices completely effective. Either the isolier materials (the extract) or the remaining material (the raffinate) may be of interest. The process of Isolation or extraction of solids by density Gases or supercritical fluids is called a supercritical Fluid extraction (SFE; SFE = supercritical fluid extraction) designated. The chromatography process, the mobile phase used which are dense gases is considered supercritical Fluid chromatography (SFC; SFC = supercritical fluid chroma tography). The SFC is the mobile phase a fluid that is generally close to temperatures and pressures  the critical point of the same is subjected. Fluids at these conditions have densities that are much closer to those of liquids, but often characteristics a greater solution product diffusion than liquids demonstrate. The SFC is therefore sometimes considered a necessary Intermediate link between gas chromatography (GC; GC = gas chromatography) and liquid chromatography (LC; LC = liquid chromatography).

The pump system is one of the most complex components in egg an analyzer that uses fluids at high pressure det. For example, the equipment is to be carried out an SFC due to the requirements for operation very high pressures to produce much more expensive than the Ge equipment for performing a GC. A conventional Equipment for performing a capillary SFC typically works between 70 × 10⁵ Pascal (70 bar) and 600 × 10⁵ Pascal (600 bar). In contrast, a typical gas chromatograph with a pressure programmable speed generally at pressures less than 10 × 10⁵ Pascal (10 bar) operated. Hence the relatively high ones Cost of SFC device equipment there are many potential users from holding an SFC.

The development of suitable high pressure pump systems was followed generally three clearly different designs: pneuma table amplifier, a reciprocating piston and a syringe.

A pneumatic booster pump has a piston the between two neighboring pump chambers (one Nieder pressure chamber and a high pressure chamber) is attached. The Chambers have different piston cross-sectional areas and therefore offer a pressure amplification factor. Two Known methods of filling the low pressure chamber are: (a) delivering gas pressure from a high pressure Gas chamber or an air pump is regulated, and (b) that Delivering water pressure from a high pressure LC pump,  for example a pump with a back and forth movement piston. However, the former method was previously limited in its use to isobaric operation; consequently, the print programming operations required for SFE- and SFC applications are necessary to implement animals. The use of a pump back and forth moving piston in the latter process to water Delivering to the low pressure chamber enables pressure Control of the SFC fluid in the high pressure chamber of the amplifier kers. However, such a use was associated with a pump reciprocating piston serious by the Speed of response to pressure changes and the rate of ramping up and down pressure limited.

Pumps with reciprocating pistons, the one Single, double or triple pump heads were included modified for SFC applications. A single pump head sy stem with a pulse damper was designed for isocratic SFC users with an open, tubular column and micro diameter ser packed column used, where low flow rates and small pressure pulses with a little damper and one Pillar can be damped. However, for this and others the typical reciprocating motion pump noisy, requires considerable pulse damping on it rem output and usually requires a device to Cooling the pump head.

A syringe pump is therefore the most common ver applied fluid delivery system to perform an SFE and egg a SFC. However, the typical syringe pump shows a long one and frequent refill time; requires an elaborate, lei powerful engine and a motor driver power supply supply and has many parts that require maintenance. The syringe pump is much more complex to manufacture and to close operate than is desired.

It is the object of the present invention a little  to create elaborate pumping system for use with Applications of high pressure fluids to analytical processes, for example the SFE or the SFC.

This object is achieved by a pump system according to claim 1 solves.

It is also an object of the present invention, Ana To create lysis devices that ver such a pump system turn.

This object is solved by claims 10, 15 and 19.

Another object of the present invention is in, a method of delivering a high pressure fluid create.

This object is achieved by a method according to claim 20 solves.

According to a first aspect of the present invention found that complex print programming of a Fluids at very high pressures thanks to a new Pumpsy stem that can be supplied with a pneumatic amplifier kerpump, a pressure regulator and an electronic pressure control system used. The electronic pressure control is applied to a first fluid such that the pre lie of the first fluid with a first fluid pressure in egg ner low pressure chamber of the pneumatic booster pump possible that an amount of a second fluid in a High pressure chamber of the pneumatic booster pump is present, is compressed to a pressure, for example for Use in supercritical fluid applications is suitable. It has been found that such a print programming the outlet pressures reached or exceeded by a conventional high pressure fluid pumping system (e.g. a syringe pump), but with a ge less effort and with greater reliability.  

According to a second aspect of the present invention found that the aforementioned pump system without white teres and low expenditure for use in a capillary SFC device for performing a quick disconnect relative non-volatile and labile compounds are adapted can. The preferred embodiment of the SFC device ver uses capillary SFC columns.

According to a third aspect of the present invention found that the aforementioned pump system in one Device for performing supercritical fluid extraction a component from a sample can be used.

According to a fourth aspect of the present invention found that the aforementioned pump system in one Device for performing a solid phase extraction of a Component from a sample can be used.

The preferred embodiment of a pump system can constructed according to the present invention to a pneumatic booster pump and electronic pressure control system for detecting the pressure of a first fluid, that to a low pressure chamber in the pneumatic amplifier kerpump is delivered to have. The pressure of the first Fluids is consequently directly on a set point- Pressure controlled. The pressure of the first fluid can correspond a printing program that is in the electronic printing control system is implemented on the set point being held. A lot of a second fluid that is in a high pressure chamber is supplied in the pumping system thereby according to the gain factor of the pneumatic Ver booster pump to a second fluid pressure under pressure puts. Therefore, the second fluid pressure is indirectly caused by the electronic pressure control system for direct control of the first fluid pressure controlled.

The pump system under consideration can be integrated into an SFC device  be, in which the pressurized second fluid to a Injector for receiving a sample directed which can be a mixture of the sample and the under pressure second fluid then placed at the inlet of a separation column can be delivered. Sample components on the Column outlet are then eluted by a detector detectable.

The pump system under consideration can be integrated into an SFE device be, in which the pressurized second fluid to a Extraction section directed to process a sample becomes.

The pump system under consideration can be converted into a solid phase Ex traction device can be integrated, in which the under pressure put second fluid to an extraction section to sam samples can be conducted.

Preferred embodiments of the present invention are referred to below with reference to the attached drawing nations explained in more detail. Show it:

Figure 1 is a schematic representation of a novel pumping system constructed in accordance with the present invention.

Fig. 2A is a schematic illustration of an apparatus using the pumping system of Fig. 1 to perform a capillary SFC;

FIG. 2B is a schematic illustration of an apparatus using the pump system of FIG. 1 to perform an over critical fluid extraction;

FIG. 2C and 2D are schematic representations of respective Ge Chambers, which contractions, the pumping system of Figure 1 for performing multiple, simultaneous, supercritical Fluidex use.

Fig. 2E is a schematic representation of an apparatus using the pump system of Fig. 1 to perform solid phase extraction;

Fig. 3 is a schematic representation of a pneumatic booster pump which can be driven in the system of Fig. 1; and

Fig. 4 is a schematic representation of an electronic pressure control system for effecting electronic control of the pump's pressure system of Fig. 1,.

Preferred embodiments of the present invention will now be described with reference to FIGS. 1 to 4, in which equivalent components are indicated by the same nomenclature and the same reference numerals. For purposes of clarity, the schematic representation of circuits carrying electronic signals is shown in single lines, whereas fluid-carrying channels are shown in double lines.

As shown in FIG. 1, according to a special feature of the present invention, a novel pump system can be constructed to have a first fluid supply 10 A, which is preferably a high pressure supply in the form of a high pressure gas cylinder made of compressed gas or an air pump . The first fluid supply 10 A supplies a gas, for example compressed air or nitrogen, through a flow resistor 11 to a pneumatic booster pump 12 . An electronic pressure control system (EPC system; EPC = electro nic pressure control) 14 is provided to a Druckreg ler 14 A for controlling a first controlled pressure in the first fluid for the purpose of insertion. The pneumatic booster pump 12 receives an amount of the first fluid at the first fluid pressure and an amount of a second fluid from a second fluid supply 10 B. That is, by operating the EPC system to control the first fluid pressure and activate one to control the switching valve in the pneumatic booster pump 12, may be effected in that the first and second fluids respective low- and high-pressure chambers fill in the pneumatic booster pump 12th The pressure of the first fluid in the pneumatic booster pump 12 causes the second fluid to be pressurized to a desired two fluid pressure. The flow of the second fluid from pump 12 , after being subjected to such controlled pressurization, is considered herein to be the pressurized second fluid.

Specifically, the desired pressures of the first and second fluids are programmable according to a pressure profile that is generated and applied for the first fluid by the EPC system 14 . In other words, the pressure programming that is directly applied to the first fluid by the EPC system 14 is used to indirectly control the pressure of the second fluid.

The preferred pumping system includes a pressure sensor 20 for generating a pressure information signal representative of the pressure of the first fluid, which is of the pneumatic booster pump 12 supplies Ge, or, alternatively, to generate a pressure sensor 20 A, a pressure information signal indicative of the un ter Pressurized second fluids as delivered to the injector 16 represents. Since the sensors can be subjected to 20 or 20 A factors, for example temperature changes or vibration, a solid-state pressure sensor is preferred in order to combine a temperature compensation circuit with a digital control for precise pressure control without the need for calibration.

In a preferred embodiment, the Druckreg ler 11 A in the form of a modulation control valve vorgese hen, the EPC system 14 is used to cause that the opening time of an opening is modulated in the valve. In one embodiment, wherein the pressure regulator is provided 14 A in the form of a proportional control valve, the EPC system 14 is used alternatively to act to be that the opening amount of an aperture is modulated in the valve. Consequently, the pressure regulator 14 A is preferably provided in the form of a high pressure valve.

In the illustrated embodiment, the pressure information signal is provided to the EPC system 14 to provide forward pressure control of the first fluid. Other modes of pressure control of the first fluid are also contemplated by the present invention.

A pumping system constructed in accordance with the present invention offers an advantage over the pumping systems used in conventional SFE and SFC systems because, for the first time, the implementation of one or more desired pressures of a supercritical fluid electronically the operation of a pneumatic booster pump can be implemented. Such regulation is achieved primarily in the EPC system 14, which will be described later herein, wherein a pressure set point and control voltage are established and used to control the Druckreg ler 14 A.

Referring to FIG. 2A, it can be seen that an apparatus 100 for performing an SFC can be constructed in which the pressurized second fluid is passed through an injector 16 into the inlet of a capillary column 18 . The sample to be separated is introduced into the injector 16 by a sampling system, or as shown by a syringe 15 , to inject the sample into the flow of the pressurized second fluid, thereby creating a sample-fluid mixture is delivered. The column 18 is arranged in an oven 24 which maintains a temperature in the sample-fluid mixture which is necessary for supercritical or almost supercritical operation. The illustrated device 100 can then be used to enable rapid separation of the sample in the sample-fluid mixture as it moves through the capillary column 18 . A suitable furnace 18 and EPC system 14 are available in the Hewlett-Packard Model 6890 Gas Chromatograph.

The preferred capillary column 18 for performing a capillary SFC, as described herein, generally uses a coated capillary or micro-packed SFC column structure with an inner diameter of less than about 500 microns. The useful range of the inner diameter is usually from about 25 to 200 microns, and more preferably from 50 to 100 microns. The column flow rate in such columns is generally less than 10 microliters per minute.

The outlet from the capillary column 18 is sent to one or more analyzers, such as a detector, to generate a chromatogram. In the preferred embodiment, the outlet from the capillary column 18 is directed through a fluid resistor 30 to a suitable GC detector 28 . A suitable GC detector is a flame ionization detector (FID = FID = flame ionization detector), as is available, for example, in the Hewlett-Packard Model 6890 gas chromatograph.

Referring to FIG. 2B, it can be seen that an SFE device 101 may be constructed in which the pressurized second fluid is pumped through the pump 12 through a sample contained in an extraction section 106 . Because the sample is embedded in the flow path, the pressurized second fluid releases material from the sample and subsequently encounters a pressure drop at a restriction device 108 . The restriction device 108 acts as a restriction device that causes a pressure drop in the high pressure solution of the sample components such that the components in the dissolved material are recovered when they are precipitated from the expanding sample fluid mixture.

As already mentioned, the sensor 20 can be arranged in various ways in order to deliver a pressure detection signal to the EPC system 14 . The sensor 20 may be arranged to allow the EPC system 14 to monitor the pressure of the first fluid in the low pressure chamber of the pump 12 . Alternatively, the sensor 20 C can be used as shown in a flow position above the extraction section 106 ; alternatively, it could be positioned as a sensor 20 D in terms of flow below the extraction section 106 .

Referring to FIGS. 2C and 2D, it can be seen that eg large second and third preferred embodiments 102, 103 of an SFE apparatus may be constructed to traction portions-simultaneous extraction of samples in a plurality of Ex 106 A, 106 B and 106 C and respective Ex traction devices 108 A, 108 B, 108 C. The SFE device 102 has a single pump 12 . The SFE device 103 has a plurality of respective pumps 12 A, 12 B and 12 C. Each pump 12 A, 12 B, 12 C receives a first fluid which is supplied by a respective pressure regulator 14 A, 14 B, 14 C. Each controller is under the control of one or more control signals from a 14 M multi-channel EPC system.

Referring to FIG. 2E, it can be seen that a preferred embodiment 104 of a solid phase extraction device can be constructed to allow simultaneous extractions of one or more components in multiple samples in fluids. The embodiment contemplates a plurality of sample containers SA, SB, each of which contains a sample fluid that can be supplied to the pump 12 as a second fluid for pressurization. That is, a switching valve 111 enables a selected flow of a sample fluid from either the sample container SA or SB to be compressed by the pump 12 in accordance with the operation of the pump system described herein.

The pressurized second fluid is passed through a switching valve 112 to a selected one of a plurality of extraction cassettes 107 A, 107 B, 107 C. Each cassette 107 A, 107 B, 107 C is filled with a preset solid phase adsorbent material such that one or more components of interest in the pressurized second fluid (e.g., a trace element in a water sample) can be recovered during the Rest of the pressurized second fluid is passed through a respective switching valve 109 A, 109 B, 109 C to a disposal line W. When the flow of the second fluid flow from the sample containers SA, SB is interrupted, a further flow of a second fluid in the form of a collection solvent is supplied from a collection fluid supply SC, compressed by the pump 12 and through the switching valve 112 to the appropriate one of the extraction cassettes 107 A, 107 B, 107 C. The flow of the collecting fluid through the extraction cassette removes the component of interest, the resulting mixture being passed via a respective switching valve 109 A, 109 B, 109 C to a collecting vessel 110 A, 110 B, 110 C. The extraction cassettes 107 A, 107 B, 107 C can be constructed as packed with a suitable adsorption medium or filled with a relatively inert matrix which has been coated or impregnated with an adsorption medium. An example of a suitable adsorbent medium / matrix is a Teflon disk matrix impregnated with an adsorbent material and commercially available as a component gallery from the 3M Company of Minneapolis, Minnesota.

As disclosed term by additional reference to FIG. 3, Lich, the electronic pressure control system controls (EPC System) 14 in order to indirectly regulate the pressure of the first fluid, which is supplied to the pneumati rule booster pump 12 the pressure of the second fluid. According to this invention, the booster pump 12 has a first fluid supply connector 33 A, which is connected to a low-pressure chamber 34 , a switching valve 33 B, which is connected to a high-pressure chamber 36 , a floating piston 35 , the low-pressure seals 35 A and high-pressure seals 35 B, and an optional cooling system 37 . As shown, the piston 35 is shown in dashed lines in a position it occurs when a compression cycle begins, in which the second switching valve 33 B can be operated to allow an amount of the second fluid to fill the high pressure chamber . Piston 35 is also shown in solid lines in a second position that occurs at the end of the compression cycle. Between the onset and end of a compression cycle, the switching valve 33 B can be operated to close the high pressure chamber 36 such that the amount of the second fluid is pressurized to a predetermined elevated pressure and therefore for delivery at a very high level Pressure (in some applications), for example as a supercritical fluid.

A typical compression cycle should be understood as follows. The first fluid supply connector 33 A enables the low pressure chamber 34 to be balanced with a zero or low pressure set by the regulator 14 A. The switching valve 33 A is then set to a first position in which the high-pressure chamber 36 receives a flow of the second fluid from the second fluid supply 10 B. While the second fluid is allowed to fill the high pressure chamber 36 , the piston 35 is driven to its lowest position. Thereafter, the switching valve 33 B is closed, and the EPC system 14 causes a pressurized flow of the first fluid from the pressure regulator 14 A to the Niederdruckkam mer 34th The pressure of the first fluid multiplied by the gain factor causes the piston 35 to compress the second fluid in the high pressure chamber 36 . The piston 35 moves upward until a predetermined pressure of the second fluid in the high pressure chamber 36 is reached, whereupon the upward movement of the piston 35 ends.

The booster pump 32 is then ready to deliver the amount of the second fluid at a pressure maintained according to the pressure of the first fluid in the low pressure chamber 34 and the pneumatic amplification factor (AF) of the pneumatic booster pump 32 . The ratio of the piston cross-sectional area at the low pressure chamber 34 and the high pressure chamber 36 is equal to the pressure amplification factor from the low pressure chamber to the high pressure chamber.

When the switching valve is switched to a fluid delivery position, the amount of the second fluid, still under pressure, is available for use in an analyzer. During delivery, and as piston 35 continues its upward motion, EPC system 14, in certain embodiments, may be programmed to maintain control of the first fluid pressure to provide continued flow of the first fluid during that second fluid from the high pressure chamber 36 flows through the switching valve 33 B.

In another preferred embodiment of the invention, the control by the EPC system 14 causes the pressure of the first fluid in the low pressure chamber 34 to be set to allow set point control of the second fluid pressure to one or more predetermined set points. As a result, the second fluid can be supplied with an ongoing selectable pressure or a range of pressures.

In an SFC application and depending on the cavity of the column 18 and the duration of the chromatographic analysis of the piston 35 continues its upward movement continues, is ejected to the entire second fluid from the high pressure chamber 36, or until the switching valve is switched 33 B in a closed position is, or both. To avoid a pressure discontinuity, or an effect known as a wave effect, during the reset phase, the preferred embodiment of the booster pump 32 is constructed such that: a) the maximum desired pressure of the second fluid is continuously delivered to the column 18 can; and b) at least one chromatogram can be fully detected at such maximum pressure before the piston reaches the end of its upward stroke. Other features of the construction of the amplifier pump 32 can be achieved according to known principles; for example, the ratio of the cross-sectional area of the low-pressure chamber to the cross-sectional area of the high-pressure chamber can be selected in order to determine the required amplification factor (AF).

Preferred gain factors are considered to be in the range of 20 to 500. The first fluid can be supplied preferably at selectable pressures of up to 15 × 10⁵ Pascal (15 bar); the second fluid is preferably delivered with pressures up to 2,000 × 10⁵ Pascal (2,000 bar). Therefore, if a flow of the first fluid is supplied at a first fluid pressure of 10 x 10⁵ Pascal (10 bar) and the piston 35 provides a gain factor of 100, the second fluid pressure can be set and maintained at 1,000 x 10⁵ Pascal (1,000 bar) .

As shown in FIG. 4, the EPC system 14 preferably has a user interface 38 , a computer 40 and a controller 42 . Although computer 40 is shown as a single block, such a computer has a central processing unit and all associated peripherals and other associated electronic components. As such, computer 40 has a memory 41 in which information and programming can be stored and retrieved by known methods. One or more additional computers 39 can provide control and data signals to computer 40 . The programming associated with computer 40 used with the present invention will become apparent in connection with the following description. Computer 40 may also be programmed to maintain overall control of other systems associated with device 100 or 102 , as is known in the art.

The user interface 38 preferably has a display device. Consequently, display or prompt messages can be generated by the computer 40 and displayed on the user interface 38 . A control circuit 42 is used to control the pressure regulator 14 . According to the illustration, the controller 42 has a second computer 44 , which in the preferred embodiment has an embedded microprocessor and its associated peripheral components.

Information can be entered by the user by means of the user interface 38 or by further computers 39 . Computer 40 operates to store the entered information in memory 41 for later access by computer 44 . Initial parameters relating to the pressure profile caused by the pressure regulator 14 A during the analysis can be entered. In the preferred embodiment, a desired pressure is calculated by computer 40 for a given time during the analysis of certain system operating parameters. Accordingly, the present invention, which takes into account the calculated desired pressure, is used to provide a control signal.

In a preferred embodiment, the first fluid flow is subjected to electronic proportional pressure control. The pressure regulator 14 A is thus constructed as a proportional control valve to incrementally open or close to maintain a desired pressure, the change in opening area being approximately proportional to the change in control voltage applied to the valve. In the feedforward system, as shown in Fig. 1, the pressure sensor 20 is arranged in terms of flow below the pressure regulator 14 A. If the downstream pressure rises slightly, the pressure sensor voltage will rise. This voltage is transmitted via a suitable signal line to the EPC controller 42 , through an analog / digital converter (A / D converter) 50 and into a digital control circuit 44 . In response, a new and somewhat lower control voltage is returned to the 14 A pressure regulator. The generated control signal can have a digital form and can consequently be converted into an analog form by the digital / analog converter 46 and appropriately amplified by the amplifier 48 before being transmitted to the pressure regulator 14 A. The open area of the valve is slightly reduced, which results in a somewhat smaller flow through the pressure regulator 14 A and a somewhat lower pressure at the pressure sensor 20 . This feedback process takes place at a relatively high frequency, which results in very smooth and repeatable pressure control of the first fluid supplied to the pneumatic booster pump 12 .

System operating parameters and system device parameters can also be entered into the computer 40 via the user interface 38 . In the preferred embodiment, the system operating parameters may include information that includes the desired pressure profile of the pressurized second fluid, the identification of the type or composition of the fluid used, the column outlet pressure, or the viscosity that a first fluid and / or a second fluid are assigned if such information does not already exist in the memory 41 of the computer 40 . Such information would contain the absolute viscosity of the special fluid for different temperatures. The temperature range over which such a viscosity would exist corresponds directly to the temperature range or the temperature profile that is to be delivered by the furnace 24 . The system device parameters would include the length and diameter of the column 18 and the characteristics of the restriction device 108 , etc. The computer 40 may prompt the user to enter data related to the various operating parameters on the user interface 38 .

It is obvious that the first fluid is of a large size Range of gases and liquids, for example air, Nitrogen, helium, water and a hydraulic fluid can be selected. It is obvious that the two fluid from pure fluids, modified fluids or ter tertiary fluids containing additives can be selected. As examples, pure fluids include the following: methanol or another alcohol, ethanol, nitrogen, helium, coal dioxide, nitrogen oxide, sulfur hexafluoride and trifluoromethane. Modified fluids include the following: methanol or one other alcohol, acetonitrile, tetrahydrofuran, hexane or other mixtures with one of the fluids that are pure under Fluids are called. Modified fluids can do more than a modifier, more than one major fluid, or both more than one modifier and more than one fluid hold. Tertiary fluids can be any of the mixtures of the above mentioned modified fluids with the addition of polar Addi tive, for example trifluoroacetic acid, isopropylamine or a raw material of others that are mentioned in the literature, contain.

Claims (20)

1. Pump system for supplying a high pressure fluid with the following features:
an electronic print control system ( 14 ) for providing a control signal according to a print program;
first and second fluid supply devices ( 10 A, 10 B) for delivering respective first and second fluids;
a pressure regulator ( 14 A) for receiving the first fluid and the control signal and in response to causing a first fluid pressure in the first fluid; and
a pneumatic booster pump ( 12 ) having a gain factor and means for receiving an amount of the first fluid at the first fluid pressure and means for receiving an amount of the second fluid;
wherein the presence of the first fluid with the first fluid pressure in the pneumatic booster pump causes the amount of the second fluid in the pneumatic booster pump to be pressurized according to the booster factor; and
whereby the pressurized second fluid is supplied as the high pressure fluid. 2. The pump system of claim 1, further comprising a sensor ( 20 , 20 A) for sensing at least one of the first fluid pressure and the pressure of the pressurized second fluid and for providing a respective data signal to the electronic pressure control system, the first Fluid pressure is caused in response to the data signal. 3. Pump system according to claim 1 or 2, wherein the pneumatic booster pump ( 12 ) further a Niederdruckkam mer ( 34 ) for receiving the first fluid with the first fluid pressure and a high pressure chamber ( 36 ) for receiving the second fluid and a piston ( 35 ) which is movable in the low pressure chamber and the high pressure chamber. 4. Pump system according to one of claims 1 to 3, wherein the pressure regulator ( 14 A) further comprises a valve which responds to the control signal. 5. Pump system according to one of claims 1 to 4, in which the first fluid is a gas and the first fluid supplier supply device also a high-pressure gas chamber points. 6. Pump system according to one of claims 1 to 5, in which the second fluid is selected from the following group:
pure fluids, modified fluids and tertiary fluids containing additives. 7. Pump system according to one of claims 1 to 6, in which the first fluid pressure between 1 × 10⁵ Pascal and 15 × 10⁵ Pascal (1 and 15 bar). 8. Pump system according to one of claims 1 to 7, in which the second fluid pressure with a pressure of between 1 × 10⁵ and 2,000 × 10⁵ Pascal (1 and 2,000 bar) becomes. 9. Pump system according to one of claims 1 to 8, wherein the electronic pressure control system ( 14 ) further comprises means ( 40 , 41 ) for determining the pressure program. 10. Apparatus for performing supercritical fluid chromatography on a sample with the following features:
a pump system ( 100 ) for delivering a supercritical fluid, which has the following features:
an electronic print control system ( 14 ) for providing a control signal in accordance with a print program;
first and second fluid supply devices ( 10 A, 10 B) for delivering respective first and second fluids;
a pressure regulator ( 14 A) for receiving the first fluid and the control signal and in response to acting a first fluid pressure in the first fluid; and
a pneumatic booster pump ( 12 ) having a gain factor and means for receiving an amount of the first fluid at the first fluid pressure and means for receiving an amount of the second fluid;
wherein the presence of the first fluid with the first fluid pressure in the pneumatic booster pump causes the amount of the second fluid in the pneumatic booster pump to be pressurized according to the gain factor; whereby the pressurized second fluid is supplied as a supercritical fluid;
an injector ( 16 ) for combining the sample and the supercritical fluid in a sample-fluid mixture;
a separation column ( 18 ) for receiving the sample-fluid mixture and for eluting a sample component; and
a detector ( 28 ) for determining the presence of the sample component. 11. The apparatus of claim 10, wherein the separation column further has a capillary column. 12. The apparatus of claim 11, wherein the capillary column fer ner an inner diameter in the range of 25 to 200 µm. 13. The apparatus of any one of claims 10 to 12, further comprising a sensor for detecting at least one of the first or the second fluid pressure and to deliver one each data signal to the electronic pressure control ersystem, wherein the second fluid pressure as Re action on the data signal is effected. 14. Device according to one of claims 10 to 13, wherein the second fluid pressure with a pressure of between 1 × 10⁵ and 2,000 × 10⁵ Pascal (1 and 2,000 bar) becomes. 15. Apparatus for performing a supercritical fluid extraction of a component in a sample with the following features:
a pump system ( 101 ) for delivering a supercritical fluid, which has the following features:
an electronic print control system ( 14 ) for providing a control signal in accordance with a print program;
first and second fluid supply devices ( 10 A, 10 B) for delivering respective first and second fluids;
a pressure regulator ( 14 A) for receiving the first fluid and the control signal and in response to acting a first fluid pressure in the first fluid; and
a pneumatic booster pump ( 12 ) having a gain factor and means for receiving an amount of the first fluid at the first fluid pressure and means for receiving an amount of the second fluid;
wherein the presence of the first fluid with the first fluid pressure in the pneumatic booster pump causes the amount of the second fluid in the pneumatic booster pump to be pressurized according to the gain factor; whereby the pressurized second fluid is supplied as a supercritical fluid;
an extraction section ( 106 ) for receiving the sample and the supercritical fluid and dissolving the sample in the supercritical fluid to form a sample-fluid mixture; and
a restriction device ( 108 ) for receiving the sample-fluid mixture and for recovering the component of the sample. 16. The apparatus of claim 15, further comprising a sensor for Capture at least either the first or the second Fluid pressure and to provide a respective data i gnals to the electronic pressure control device points, the second fluid pressure in response to the Data signal is effected. 17. The apparatus of claim 15 or 16, further comprising a more has number of extraction sections that are effective  are connected to the pump system, the second Fluid flow to the plurality of extraction sections is delivered, creating a variety of extractions can be performed simultaneously. 18. Device according to one of claims 15 to 17, wherein the electronic pressure control system a variety of tax provides signals, and further a plurality of respective pneumatic booster pumps, pressure regulators and extraction sections, each of the pneumatic booster pumps a first fluid flow from a respective controller with a respective pressure that determined according to one of the control signals and each of the pneumatic booster pumps is effective to a respective second fluid flow a selected one of the plurality of extraction portions cut to deliver, creating a multitude of extracts tion can be carried out simultaneously. 19. Apparatus for performing solid phase extraction of a component in a sample with the following features:
a pump system ( 102 ) for supplying a high pressure fluid, which has the following features:
an electronic print control system ( 14 ) for providing a control signal in accordance with a print program;
first and second fluid supply devices ( 10 A, 10 B) for delivering respective first and second fluids;
a pressure regulator ( 14 A) for receiving the first fluid and the control signal and in response to acting a first fluid pressure in the first fluid; and
a pneumatic booster pump ( 12 ) having a gain factor and means for receiving an amount of the first fluid at the first fluid pressure and means for receiving an amount of the second fluid;
wherein the presence of the first fluid with the first fluid pressure in the pneumatic booster pump causes the amount of the second fluid in the pneumatic booster pump to be pressurized according to the gain factor; whereby the pressurized second fluid is supplied as a high pressure fluid; and
an extraction cassette ( 106 A, 106 B, 106 C), which has an adsorption medium therein, for receiving the high pressure fluid and for extracting the component into the adsorption medium. 20. A method of delivering a high pressure fluid with the following characteristics:
Providing an electronic print control signal in accordance with a print program;
Delivering first and second fluids from respective first and second fluid supply devices;
Regulating the pressure of the first fluid according to the control signal to effect a first fluid pressure in the first fluid;
Providing a pneumatic booster pump with a low pressure chamber and a high pressure chamber;
Directing the second flow into the high pressure chamber;
Directing the first flow of the first fluid pressure into the low pressure chamber to effect a second fluid pressure in the second fluid, thereby pressurizing the second fluid; and
Providing the pressurized second fluid as the high pressure fluid.