Patent Publication Number: US-2023162961-A1

Title: Ionizer and mass spectrometer

Description:
TECHNICAL FIELD 
     The present invention relates to an ionizer and a mass spectrometer. 
     BACKGROUND ART 
     One type of device for analyzing a substance contained in a liquid sample is a liquid chromatograph mass spectrometer. In the liquid chromatograph mass spectrometer, a liquid sample is introduced into a column of a liquid chromatograph by being carried by a flow of a mobile phase, and a target substance is separated in the column from other substances. The target substance flowing out of the column is ionized by an ion source of the mass spectrometer, is separated according to the mass-to-charge ratio, and is then measured. 
     As an ion source of the mass spectrometer, for example, an electrospray ionization (ESI) source is used. The ESI source introduces a liquid sample into a nozzle (ESI nozzle) having a double tube structure to charge the liquid sample and sprays the charged liquid sample into an ionization chamber. The ESI source includes: a first channel into which the liquid sample is introduced; and a second channel provided on an outer periphery of the first channel into which a nebulizer gas is introduced. In the ESI source, a predetermined voltage (ESI voltage) is applied to the first channel to charge the liquid sample, and the nebulizer gas is blown to charged droplets of the liquid sample flowing out from a tip of the first channel so that the charged droplets are sprayed into the ionization chamber. The charged droplets sprayed into the ionization chamber are split by electric charge repulsion inside the droplets, and vaporization (desolvation) of the mobile phase creates ions. 
     Patent Literatures 1 and 2 describe an ESI source including a mechanism configured to supply an assist gas for promoting desolvation of the charged droplets of the liquid sample. The mechanism for supplying the assist gas includes: a third channel to which the assist gas is supplied; and an assist gas nozzle for supplying the assist gas supplied from the third channel to an outer periphery of a jet flow of the liquid sample from the ESI nozzle. A heater is disposed inside the third channel, and desolvation is promoted by the assist gas which is heated by the heater and is supplied to the charged droplets of the liquid sample. 
     CITATION LIST 
     Patent Literature 
     
         
         Patent Literature 1: JP 2011-113832 A 
         Patent Literature 2: JP 2015-049077 A 
       
    
     SUMMARY OF INVENTION 
     Technical Problem 
     In recent years, in the liquid chromatograph mass spectrometry, analysis of a wide variety of substances has been performed, and various analysis conditions are also used for the analysis. The optimum temperature of the assist gas varies depending on characteristics of a target substance and analysis conditions. Patent Literatures 1 and 2 describe that an assist gas heated to 400° C. to 500° C. is blown to charged droplets. However, in the case of analysis of a substance that is difficult to vaporize or in the case of analysis in which a mobile phase is supplied at a high flow velocity, desolvation is not sufficient, and it is required that a higher-temperature assist gas is used to promote desolvation of the charged droplets. 
     Patent Literature 2 describes that a micro-sheath heater is used as a heater to heat an assist gas. Though the micro-sheath heater has a high heat resistance temperature of about 600° C., it is made of a thin wire so that an even slightly excessive supply power could destroy the heater. When a heater having a high heat resistance is used to prevent this problem, the cost increases. 
     In the above, the problems of a conventional art have been described taking the assist gas in the ESI source as an example, but other ion sources, for example, atmospheric pressure chemical ionization (APCI) sources have the same problems as described above. 
     The problem to be solved by the present invention is to provide, at low cost, a technique capable of promoting desolvation of a liquid sample with an assist gas having a higher temperature than before. 
     SOLUTION TO PROBLEM 
     An ionizer, according to the present invention, made to solve the above problem includes:
     an ionization chamber;   a sample nozzle configured to cause a liquid sample to flow out into the ionization chamber;   an assist gas passage configured to supply, to the ionization chamber, an assist gas that promotes desolvation of the liquid sample:   a heater disposed inside the assist gas passage: and   a heat transfer member disposed in the assist gas passage in contact with the heater.   

     ADVANTAGEOUS EFFECTS OF INVENTION 
     In the ionizer according to the present invention, the assist gas for promoting desolvation of the liquid sample is supplied to the liquid sample flowing out from the sample nozzle. In the assist gas passage through which the assist gas flows, the heat transfer member in addition to the heater is disposed in contact with the heater. In the conventional ionizer, only the heater is disposed in the assist gas passage, and most of the assist gas flowing in the assist gas passage is released without contacting the heater. On the other hand, in the ionizer according to the present invention, since the heat transfer member is disposed in addition to the heater, the contact area between the assist gas flowing through the assist gas passage and a heat source (the heater and the heat transfer member) is larger than before. Therefore, the assist gas is heated with higher efficiency, and it is possible to supply the assist gas having a higher temperature than before. In addition, a heater similar to the conventional heater can be used, and the ionizer can be configured at low cost. 
    
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
         FIG.  1    is a schematic configuration diagram of a mass spectrometer including an embodiment of an ionizer according to the present invention. 
         FIG.  2    is a diagram illustrating an internal structure of a tip portion of an ESI ionization probe that is the ionizer of the present embodiment. 
         FIG.  3    is a schematic diagram of a cross-section of the tip portion of the ESI ionization probe that is the ionizer of the present embodiment. 
         FIG.  4    illustrates a stainless steel (SUS) mesh that is a heat transfer member in the present embodiment. 
         FIG.  5    is a diagram illustrating disposition of the heat transfer members in the present embodiment. 
         FIG.  6    is another diagram illustrating disposition of the heat transfer members in the present embodiment. 
         FIG.  7    is a diagram illustrating a configuration of a heater used in the present embodiment. 
         FIG.  8    is another diagram illustrating the configuration of the heater used in the present embodiment. 
         FIG.  9    is still another diagram illustrating the configuration of the heater used in the present embodiment. 
         FIG.  10    is still another diagram illustrating the configuration of the heater used in the present embodiment. 
         FIG.  11    illustrates an experimental result confirming an effect of heating the assist gas by the ionizer of the present embodiment. 
     
    
    
     DESCRIPTION OF EMBODIMENTS 
     An embodiment of an ionizer according to the present invention will be described below with reference to the drawings. The ionizer of the present embodiment is incorporated as an ionization part of a mass spectrometer, and ionizes a liquid sample containing a target substance. 
       FIG.  1    is a configuration diagram of a main part of a mass spectrometer. The mass spectrometer includes, inside a chamber  1 : an ionization chamber  2 ; a first intermediate vacuum chamber  3 ; a second intermediate vacuum chamber  4 ; and an analysis chamber  5 . In the ionization chamber  2 , there is disposed an ESI ionization probe  60  that ionizes components in the liquid sample. In the first intermediate vacuum chamber  3  and the second intermediate vacuum chamber  4 , there are respectively disposed ion guides  11  and  13  that are configured to transport ions while converging the ions. In the analysis chamber  5 , there are disposed a quadrupole mass filter  15  and an ion detector  16  that separate ions according to the mass-to-charge ratio m/z are disposed. 
     The ionization chamber  2  and the first intermediate vacuum chamber  3  communicate with each other through a thin heated capillary  10 . The first intermediate vacuum chamber  3  and the second intermediate vacuum chamber  4  communicate with each other through an ion passage hole formed at the top of a skimmer  12 . The second intermediate vacuum chamber  4  and the analysis chamber  5  communicate with each other through an ion passage opening  14 . 
     The inside of the ionization chamber  2  is in an ambience of substantially atmospheric pressure. On the other hand, the inside of the analysis chamber  5  is vacuum-evacuated to a high vacuum state of, for example, about 10 -3  to 10 -4  Pa by a high-performance vacuum pump (not illustrated). The first intermediate vacuum chamber  3  and the second intermediate vacuum chamber  4 , which are sandwiched between the ionization chamber  2  and the analysis chamber  5 , are also each vacuum-evacuated with a vacuum pump, and constitute a multistage differential pumping system in which a degree of vacuum is increased stepwise. 
     An analysis operation in the mass spectrometer of the present embodiment will be briefly described. A liquid sample for analysis is introduced into a liquid sample supply tube  7  of the ESI ionization probe  60 . The liquid sample supply tube  7  has a configuration in which, for example, a conductive passage connection jig connects two capillaries to each other, and a predetermined voltage (ESI voltage) is applied to the passage connection jig. This voltage charges the liquid sample. 
     When the liquid sample flows out of the ESI ionization probe  60 , a nebulizer gas (atomization-promoting gas) is blown to the liquid sample from the nebulizer gas supply tube  8 , and the liquid sample is sprayed into the ionization chamber  2  as fine charged droplets. Further, the assist gas, which is a heated gas, is supplied to the charged droplets sprayed into the ionization chamber  2  from the assist gas supply line  9 , so that a mobile phase (solvent) is desolvated from the charged droplets, and a substance in the sample is ionized. 
     The ions generated in the ionization chamber  2  are drawn into the heated capillary  10  by a pressure difference between the ionization chamber  2  and the first intermediate vacuum chamber  3 . The desolvation further proceeds while the charged droplets are passing through the heated capillary  10 , and the generation of ions is promoted. 
     The ions introduced into the first intermediate vacuum chamber  3  through the heated capillary  10  are converged by the action of the electric field formed by the ion guide  11 , and are introduced into the second intermediate vacuum chamber  4  through the ion passage hole at the top of the skimmer  12 . The ions are converged by the action of the electric field formed by the ion guide  13  in the second intermediate vacuum chamber  4 , and are transferred to the analysis chamber  5  through the ion passage opening  14 . In the analysis chamber  5 , only the ions having a specific mass-to-charge ratio pass through the space in the long axis direction of the quadrupole mass filter  15  and reach the ion detector  16  to be detected. Because the mass-to-charge ratio of the ions passing through the quadrupole mass filter  15  depends on a DC voltage and a radio-frequency voltage applied to the filter  15 , it is possible to scan the mass-to-charge ratio of the ions incident on the ion detector  16  over a predetermined range by, for example, scanning the applied voltage. 
     Next, a configuration of the ESI ionization probe  60  of the present embodiment will be described.  FIG.  2    is a schematic diagram of a cross-section illustrating an internal structure of the tip portion of the ESI ionization probe  60  illustrated in  FIG.  1   .  FIG.  3    is a schematic diagram of a cross-section (a cross-section orthogonal to the direction in which the liquid sample flows) of the tip portion of the ESI ionization probe  60 . In  FIG.  2   , heat transfer members  64  are not shown in order to clearly illustrate an assist gas passage  61 . 
     In the ESI ionization probe  60 , a nozzle  65  for spraying the liquid sample includes: a capillary  66  through which the liquid sample flows; and a nebulizer gas tube  67  provided coaxially with the capillary  66  on the outer periphery of the capillary  66 . The space between the outer periphery of the capillary  66  and the inner periphery of the nebulizer gas tube  67  is a nebulizer gas channel through which the nebulizer gas flows. A conductive member (not illustrated) is disposed on the upstream side of the capillary  66  illustrated in  FIG.  2   , and a charge is applied to the liquid sample by applying an ESI voltage to the conductive member. 
      Outside the nebulizer gas tube  67 . there is disposed an assist gas nozzle  63  coaxially with the capillary  66  and the nebulizer gas tube  67 . The tip portion of the assist gas nozzle  63  is formed in a tapered shape. The assist gas is supplied from an assist gas discharge hole  631  opened in an annular shape such that the assist gas surrounds the outer side of a jet flow of the charged droplets of the liquid sample ejected from the nozzle  65 . 
     A housing  68  having an annular shape is provided around the assist gas nozzle  63 . Inside the housing  68 , there is formed the assist gas passage  61 . In one place of the assist gas passage  61 , there is formed a gas inlet  611 , and on the opposite side of the housing  68  with respect to the gas inlet  611  across the center O of the housing  68 , there is formed a gas outlet  612  communicating with the assist gas nozzle  63 . 
     In the assist gas passage  61 , there are dispose: a substantially annular heater  62  covering substantially the entire circumference of the assist gas passage  61 ; and heat transfer members  64 . In the present embodiment, as illustrated in  FIG.  4   , as the heat transfer members  64 , there are used members each formed by molding a mesh made of stainless steel (SUS) into a shape corresponding to a space between the assist gas passage  61  and the heater  62  or corresponding to a space inside the heater  62 . The upper left of  FIG.  4    is a plan view of the heat transfer members  64  disposed inside the heater  62 , and the lower left is a side view of the heat transfer members  64 . The heat transfer member  64  illustrated on the right side of  FIG.  4    is a perspective view of one of the heat transfer members  64  disposed between an inner wall surface of the assist gas passage  61  and the heater  62 . 
       FIG.  5    illustrates how the heat transfer members  64  are disposed inside the assist gas passage  61  on the left side in  FIG.  2   , and  FIG.  6    illustrate how the heat transfer members  64  are disposed inside the assist gas passage  61  on the right side in  FIG.  2   . The heat transfer members  64  are disposed such that the heat transfer members  64  are in contact with the heater  62  and fill space between the inner wall surface of the assist gas passage  61  and the heater  62 . The heat transfer member  64  is also disposed inside the annular heater  62 . Inside the heater  62 . there is disposed a heat transfer member in which the heat transfer member  64  on the left side of  FIG.  4    is folded and formed in a U shape. The inside of the assist gas passage  61  is heated by the heater  62  and the heat transfer members  64  to which heat from the heater  62  is transferred.  FIGS.  5  and  6    illustrate that the heat transfer members  64  disposed in the space between the inner wall of the assist gas passage  61  and the heater  62  have an L-shaped cross-section or a linear cross-section. However, the configuration can be appropriately changed, for example, the heat transfer members  64  may have a circular cross-section. In  FIGS.  5  and  6   , the heat transfer member  64  disposed inside the heater  62  has a U-shaped cross-section, but may be appropriately changed by using a heat transfer member having a circular cross-section. The heat transfer members  64  only have to be in contact with the heater  62 , and the arrangements of the heat transfer members  64  are not limited to those illustrated in  FIGS.  5  and  6   . 
     In the present embodiment, since a SUS mesh, which is easily deformed, is used as the heat transfer members  64 , it is possible to tightly dispose the heat transfer members  64  to correspond to the shapes of the assist gas passage  61  and the heater  62 . Because the mesh-shaped heat transfer members  64  have a large number of holes, the heat transfer members  64  do not disturb the flow of the assist gas. 
     The configuration of the heater  62  will be described with reference to  FIGS.  7  to  10   . The heater  62  of the present embodiment is a micro-sheath heater and is formed in such a manner that both wing portions of one heater wire  620  formed in a substantially Y shape as illustrated in  FIG.  7    are each wound as illustrated in  FIG.  8    so as to form two heating portions  621  and  622  as illustrated in  FIG.  9   . As illustrated in  FIG.  10   , the heating portions  621  and  622  are curved in a substantially semicircular shape, and the ends of the heating portions  621  and  622  are butted against each other, thereby completing the heater  62  including the two heating portions  621  and  622  having a substantially semicircular shape. 
     Each of the two heating portions  621  and  622  is configured in such a manner that two heater wires  620  in which electric current flows in opposite directions to each other are wound in a spiral manner and the outside of the heating portion is coated with an insulating material. Therefore, the directions of the magnetic fluxes induced by the electric currents flowing through the two heater wires  620  that are in close contact with each other are exactly opposite to each other, and cancel each other. Therefore, even when a heating current flows through the heating portions  621  and  622 , an influence of the magnetic field induced by the heating current does not occur. In addition, since the heating portions  621  and  622  are coated with an insulating material, there is no concern of electric leakage, and the heater  62  can be safely used. 
     The assist gas is introduced into the assist gas passage  61  from the gas inlet  611 . The direction in which the assist gas flows from the gas inlet  611  toward the assist gas passage  61  is substantially orthogonal to the assist gas passage  61 . The gas passage from the gas inlet  611  to the gas outlet  612  includes two paths of the upper semicircular channel and the lower semicircular channel in  FIG.  3   , and the passage resistances of the both paths are substantially equal; therefore, the assist gas flows being equally divided for the upper channel and the lower channel. 
     The assist gases separately flowing in the two paths are each heated by the heater  62  and the heat transfer members  64 , join before the gas outlet  612 , and flow into the assist gas nozzle  63 . The heating portions  621  and  622  have substantially the same shape, and the heat transfer members  64  are disposed to the same extent in the two paths. The amount of the assist gas flowing through each of the two paths is approximately the same, and the gas passing through either path is heated to approximately the same temperature. Therefore, unevenness is less likely to occur in the temperature of the assist gas, and a high-temperature assist gas is stably supplied. 
     The assist gas flowing into the assist gas passage  61  from the gas inlet  611  as described above is further heated as it moves toward the gas outlet  612 ; therefore, the temperature of the assist gas near the gas inlet  611  is low, and the temperature of the assist gas near the gas outlet  612  is high. The assist gas nozzle  63  is provided at a position far from the gas inlet  611  and, to the contrary, close to the gas outlet  612 ; therefore, the assist gas heated to a high temperature by the heater  62  flows into the assist gas nozzle  63  and is discharged from the assist gas discharge hole  631  almost without being cooled. Further, the assist gas nozzle  63  is positioned away from the assist gas passage  61  in the vicinity of the gas inlet  611  where the assist gas having a relatively low temperature exists: therefore, the assist gas nozzle  63  itself is hardly cooled. Therefore, the heat from the heater  62  and the heat transfer members  64  can be used without waste, and the assist gas having a stable high temperature can be discharged from the assist gas discharge hole  631 . 
     In the conventional ionizer, only the heater  62  is disposed in the assist gas passage  61 , and most of the assist gas flowing in the assist gas passage  61  is released without contacting the heater  62 . Therefore, even when a micro-sheath heater capable of heating up to about 600° C. is used, the actually supplied assist gas is heated only up to 400° C. to 500° C. 
     On the other hand, in the present embodiment, the heat transfer members  64  in addition to the heater  62  are disposed in the assist gas passage  61 , and the contact area between the assist gas flowing through the assist gas passage  61  and the heat source (the heater  62  and the heat transfer members  64 ) is made larger than before. As a result, the assist gas is heated with higher efficiency, and the assist gas having a higher temperature than before can be supplied. In addition, as the heater  62  itself, a heater similar to a conventional heater may be used, and the ionizer can be configured at low cost. 
     Next, an experiment will be described that was conducted to confirm that the ionizer of the above embodiment improves the heating efficiency of the assist gas. In this experiment, an assist gas (air) was introduced at a flow rate of 30 mL/min, electric power of 99 V was supplied to the heater  62 , and a temperature change of the assist gas being discharged from the assist gas discharge hole  631  was measured. As a comparative example, the temperature change of the assist gas was measured under the same conditions as described above but with no heat transfer member  64  disposed. 
       FIG.  11    shows experimental results. As can be seen from the graph of  FIG.  11   , in the ionizer of the above embodiment, by disposing the heat transfer members  64 , the assist gas was heated to a higher temperature more quickly (about 50° C. higher when 15 minutes had elapsed after the start of heating). In this experiment, the heating temperature of the assist gas was kept at 450° C., but it is considered that, if electric power of the same magnitude as in the conventional art were supplied, the assist gas could be heated to a temperature higher than 500° C. 
     The above-described embodiment is merely an example, and can be appropriately modified in line with the spirit of the present invention. The above embodiment has described a case where the ionizer is used in combination with the ESI ionization probe  60 , but the ionizer can be used in combination with another ionization probe such as an ionization probe for atmospheric pressure chemical ionization (APCI), an ionization probe for atmospheric pressure photo ionization (APPI), or the like. In addition, in an ion analyzer such as a mass spectrometer or the like, when supplying a gas for heating a desolvation tube (the heated capillary  10  in the above embodiment) that takes ions generated in an ionization chamber into an analysis section in a subsequent stage, it is possible to use a configuration in which a heat transfer member is disposed in the same manner as described above. 
     In the above embodiment, the heat transfer members  64  are disposed between the assist gas passage  61  and the heater  62  and inside the heater  62 ; however, the heat transfer member  64  may be disposed only in one of them. For example, when the outer diameter of the heater  62  is near the diameter of the assist gas passage  61 , even a configuration in which the heat transfer member  64  is disposed only inside the heater  62  can sufficiently improve the heating efficiency. 
     Modes 
     It will be understood by those skilled in the art that the exemplary embodiment described above is a specific example of the following modes. 
      Clause 1 
     An ionizer according to one mode includes:
     an ionization chamber;   a sample nozzle configured to cause a liquid sample to flow out into the ionization chamber;   an assist gas passage configured to supply, to the ionization chamber, an assist gas that promotes desolvation of the liquid sample;   a heater disposed inside the assist gas passage; and   a heat transfer member disposed in the assist gas passage in contact with the heater.   

     In the ionizer according to Clause 1, the assist gas for promoting desolvation of the liquid sample is supplied to the liquid sample flowing out from the sample nozzle. In the assist gas passage through which the assist gas flows, the heat transfer member in addition to the heater is disposed in contact with the heater. In the conventional ionizer, only the heater is disposed in the assist gas passage, and most of the assist gas flowing in the assist gas passage is released without contacting the heater. On the other hand, in the ionizer according to Clause 1, since the heat transfer member is disposed in addition to the heater, the contact area between the assist gas flowing through the assist gas passage and a heat source (the heater and the heat transfer member) is larger than before. Therefore, the assist gas is heated with higher efficiency, and it is possible to supply the assist gas having a higher temperature than before. In addition, a heater similar to the conventional heater can be used, and the ionizer can be configured at low cost. 
     Clause 2 
     In the ionizer according to Clause 1,
     the sample nozzle is configured to cause an atomization-promoting gas to spray the liquid sample into the ionization chamber, and   the assist gas is supplied in such a direction as to push out a jet flow of the liquid sample ejected from the sample nozzle.   

     In the ionizer described in Clause 2. it is possible to cause the atomization-promoting gas to promote the desolvation of the jet flow of the liquid sample sprayed into the ionization chamber. 
     Clause 3 
     In the ionizer according to Clause 1 or 2, 
     the heat transfer member has a mesh shape. 
     In the ionizer according to Clause 3, since the mesh-shaped heat transfer is easily deformed is used, the heat transfer member can be disposed to correspond to the shape of the assist gas passage. Because the mesh-shaped heat transfer member has a large number of holes, the heat transfer members  64  do not disturb the flow of the assist gas. 
     Clause 4 
     An ionizer according to Clause 4 is the ionizer according to any one of Clauses 1 to 3, wherein 
     the heat transfer member is disposed between an inner wall of the assist gas passage and the heater. 
     In the ionizer according to Clause 4, it is possible to efficiently heat the assist gas flowing between the inner wall of the assist gas passage and the heater. 
     Clause 5 
     An ionizer according to Clause 5 is the ionizer according to any one of Clauses 1 to 4, wherein 
     the heater includes a spirally wound heater wire. 
     In the ionizer according to Clause 5. the heater can uniformly heat the inside of the assist gas passage. 
     Clause 6 
     An ionizer according to Clause 6 is the ionizer according to Clause 5, wherein 
     the heat transfer member is disposed inside the heater including the spirally wound heater wire. 
     In the ionizer of Clause 6, it is possible to efficiently heat the assist gas flowing inside the spirally wound heater. 
     Clause 7 
     An ionizer according to Clause 7 is the ionizer according to Clause 5 or 6, wherein 
     the heater wire is coated with an insulating material. 
     In the ionizer according to Clause 7, the heater wire is insulated, so that the ionizer can be safely used. In addition, durability of the heater wire is improved. 
      Clause 8 
     A mass spectrometer according to Clause 8 includes:
     the ionizer according to any one of Clauses 1 to 7; and   a mass spectrometry section configured to perform mass spectrometry of ions generated by the ionizer.   

     The ionizer described in any one of Clauses 1 to 7 can be suitably used as an ionization part of a mass spectrometer.  
     
       
         
           
               
               
             
               
                 REFERENCE SIGNS LIST 
               
             
            
               
                 1... 
                 Chamber 
               
               
                 2... 
                 Ionization Chamber 
               
               
                 3... 
                 First Intermediate Vacuum Chamber 
               
               
                 4... 
                 Second Intermediate Vacuum Chamber 
               
               
                 5... 
                 Analysis Chamber 
               
               
                 60... 
                 ESI Ionization Probe 
               
               
                 61... 
                 Assist Gas Passage 
               
               
                 611... 
                 Gas Inlet 
               
               
                 612... 
                 Gas Outlet 
               
               
                 62... 
                 Heater 
               
               
                 620... 
                 Heater Wire 
               
               
                 621, 622... 
                 Heating Portion 
               
               
                 63... 
                 Assist Gas Nozzle 
               
               
                 631... 
                 Assist Gas Discharge Hole 
               
               
                 64... 
                 Heat Transfer Member 
               
               
                 65... 
                 Nozzle 
               
               
                 66... 
                 Capillary 
               
               
                 67... 
                 Nebulizer Gas Tube 
               
               
                 68... 
                 Housing 
               
               
                 7... 
                 Liquid Sample Supply Tube