JP6055720B2 - Liquid chromatograph - Google Patents

Description

The present invention relates to a liquid feed pump and a liquid chromatograph.

  In the liquid chromatograph apparatus, a mobile phase is sucked by a liquid feed pump, and is sent to a separation column together with a sample introduced by a sample introduction apparatus. The sample introduced into the separation column is separated into each component and detected by various detectors.

  In general, in an apparatus field called high performance liquid chromatograph (HPLC), analysis is performed under a high pressure flow path of a maximum of 20 to 40 MPa, and in an apparatus field called ultra high performance liquid chromatograph (UHPLC), the analysis is performed under a high pressure channel of 100 to 140 MPa. Is required.

  A liquid feed pump used in such an apparatus is required to be able to supply a mobile phase accurately and precisely even under high pressure.

In Patent Document 1, as a technique for reducing the pulsation of the liquid even if the discharge flow rate is changed, the first plunger pump and the second plunger pump connected in series or in parallel are alternately sucked and compressed at a substantially constant cycle. It is described that the operation is performed so that the pressurizing chamber of at least one plunger pump is in a higher pressure state than the others, and the flow rate is controlled by adjusting the lift amounts of the first plunger and the second plunger.

JP 2012-32187 A JP-A-5-306302

  In liquid feeding control called a gradient method, mixing is performed so as to change the composition of a plurality of types of solvents. In an analyzer such as a liquid chromatograph, in order to reduce the noise of the detector, it is necessary to sufficiently mix them to reduce the concentration unevenness and make it uniform in the flow direction.

  Patent Document 1 describes the configuration of a liquid chromatograph feed pump that performs solvent mixing under high-pressure conditions and a control method therefor. However, Patent Document 1 does not consider any solvent mixing efficiency. Further, in the configuration of the liquid feed pump described in Patent Document 1, it is not suitable to cause fluctuations in the flow of the liquid after mixing, causing noise in the analysis result.

  In addition, as a technique related to liquid mixing, Patent Document 2 describes that the liquid mixing effect is enhanced by an extended tubular container having a circular cross section and a pulsating flow reactor having a baffle plate on the inner wall of the container. ing.

  However, when an analyzer such as a liquid chromatograph is equipped with a structure such as the above pulsation reactor, the dead volume increases by the amount of the baffle and affects the analysis result, which is not preferable. Further, since the flow rate pulsation of the liquid becomes a noise of the detector, it is necessary to keep the discharge flow rate of the liquid feeding pump constant.

  An object of the present invention is to provide an apparatus capable of improving the mixing accuracy of a solvent and suppressing noise in an analysis result, and a method using the apparatus.

As an aspect for achieving the above object, in the present invention, a first pressurizing chamber having a first suction passage and a first discharge passage, and a first reciprocating motion in the first pressurizing chamber are provided. A first pump unit comprising a plunger, a second pressurization chamber having a second suction passage and a second discharge passage, a second plunger reciprocating in the second pressurization chamber, a second pump unit and a connection flow path for connecting said first pump unit and the second pump unit, a drive unit for driving the first and second plungers, the first A pressure detector that detects the pressure of fluid discharged from at least one of the second pump units, valve means for switching a plurality of liquids sucked by the first pump unit, and a plurality of the sucked liquids and the merging section to join, shed those該合A mixing unit for mixing the body, and a control unit for controlling the drive unit, wherein the control unit, with keeping the flow rate of the liquid passing through the discharge flow path of the second pump unit constant, the merging An apparatus characterized by controlling the driving section so as to pulsate the liquid that has passed through the section, and a method using the apparatus.

According to the above aspect, in the liquid chromatographic analysis, it is possible to improve the mixing accuracy of the solvent and to suppress noise in the analysis result.

The figure which shows the structure of the liquid chromatograph apparatus which concerns on Example 1 of this invention. The figure which shows the graph of the time change of the displacement of the plunger which concerns on Example 1 of this invention, the pressure of a plunger pump, flow volume, and the state of a solenoid valve. The figure which shows the graph of the time change of the moving speed of the plunger which concerns on embodiment of this invention. The figure which shows the other example of the graph of the time change of the moving speed of the plunger which concerns on embodiment of this invention. The figure which shows the further another example of the graph of the time change of the moving speed of the plunger which concerns on embodiment of this invention. The figure which shows the graph of the time change of the moving speed of the plunger which concerns on embodiment of this invention. The figure which shows the structure of the liquid mixer which concerns on embodiment of this invention. The figure which shows the example of a structure of the phase shift part in the liquid mixer which concerns on embodiment of this invention. The figure which shows the other example of a structure of the phase shift part in the liquid mixer which concerns on embodiment of this invention. The figure which shows the structure of the liquid chromatograph which concerns on Example 2 of this invention. The figure which shows the graph of the time change of the displacement of the plunger which concerns on Example 2 of this invention, a pressure, flow volume, and the state of a solenoid valve. The figure which shows the structure of the liquid chromatograph which concerns on Example 3 of this invention. The figure which shows the graph of the time change of the displacement of the plunger which concerns on Example 3 of this invention, a pressure, flow volume, and the state of a solenoid valve. The figure which shows the structure of the liquid chromatograph apparatus which concerns on Example 4 of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  In this embodiment, an example of a liquid chromatograph using a liquid feed pump in which a first plunger pump and a second plunger pump are arranged in series and a liquid mixer is arranged upstream of the first plunger pump will be described. To do.

  FIG. 1 is a diagram illustrating the configuration of the liquid chromatograph apparatus according to the first embodiment.

  In FIG. 1, the main components of the liquid feed pump 1 are a first plunger pump 101, a second plunger pump 102, a first electromagnetic valve 81, a second electromagnetic valve 82, a liquid mixer 92, a controller 50, They are a motor driver 106 and a solenoid valve driver 107. In the first plunger pump 101, a first suction passage 10, a first discharge passage 103, and a first pressurizing chamber 12 are formed. A check valve 4 and a check valve 5 are arranged on the passages of the first suction passage 10 and the first discharge passage 103, and are respectively held in one direction by a spring to restrict the flow direction of the solvent liquid. It is a check stop valve. In the second plunger pump 102, a second suction passage 104, a second discharge passage 11, and a second pressurizing chamber 13 are formed. The first discharge passage 103 and the second suction passage 104 are connected by a connection passage 24. That is, the first plunger pump 101 and the second plunger pump 102 are arranged in series, and the first plunger pump 101 is installed on the upstream side. In the first plunger pump 101, the first plunger 2 that is a pressurizing member is slidably held by a bearing 71. In the second plunger pump 102, the second plunger 3, which is a pressurizing member, is slidably held by a bearing 72.

  The rotation of the first electric motor 211 is decelerated by the speed reducer 221 and converted into a linear motion by the linear motion device 231 to reciprocate the first plunger 2. Similarly, the rotation of the second electric motor 212 is decelerated by the speed reduction device 222 and converted into a linear motion by the linear motion device 232 to drive the second plunger 3 back and forth.

  Here, the speed reduction device 221 and the linear motion device 231 can be called a power transmission mechanism device in a broad sense because they combine these to amplify the rotational power of the electric motor 211 and convert it into a linear motion force. Specific examples of the reduction gear 221 include a spur gear, a pulley, a planetary gear, and a worm gear. The main reason for providing the reduction gear is to increase the torque of the electric motor. If the electric motor itself has a capability of generating sufficient torque, it is not always necessary to install it. Specific examples of the linear motion device 231 include a ball screw, a cam, and a rack and pinion, and any structure that can convert rotational motion into linear motion is applicable. The seal 61 prevents liquid leakage from the first pressure chamber 12, and the seal 62 prevents liquid leakage from the second pressure chamber 13.

  When the first plunger pump 101 performs a suction operation, one of the solenoid valve 81 and the solenoid valve 82 is open and the other is closed, and the solvents 511 and 512 are not sucked simultaneously. The sucked solvent is sucked into the first pressurizing chamber 12 through the junction portion 91, the liquid mixer 92, the first suction passage 10, and the check valve 4, and then compressed and the first discharge passage 103. Then, the air is sucked into the second pressurizing chamber 13 through the connection flow path 24 and the second suction passage 104 and is discharged from the second discharge passage 11.

  The liquid mixer 92 is provided to promote mixing of the solvents 511 and 512, and the configuration thereof will be described later with reference to FIG. A sample to be analyzed by the injector 53 is injected into the solvents 511 and 512 discharged from the liquid feed pump 1.

  The solvents 511 and 512 into which the sample is injected enter the separation column 54 and are separated for each component, and then the detector 55 detects the absorbance, fluorescence intensity, refractive index, and the like corresponding to the sample component. The separation column 54 is filled with microparticles, and a load pressure of several tens of megapascals to over 100 megapascals is generated in the plunger pump due to fluid resistance when the solvent flows through the gaps between the microparticles. The magnitude of this load pressure varies depending on the diameter of the separation column and the passing flow rate.

  The controller 50 gives command values to the motor driver 106 and the electromagnetic valve driver 107 based on signals from the pressure sensors 60 and 105. The motor driver 106 applies driving power to the electric motors 211 and 212 based on the command value of the controller 50, and the electromagnetic valve driver 107 supplies driving power to the electromagnetic valves 81 and 82 based on the command value of the controller 50.

  Here, an example of a graph of the rotational speed of the electric motors 211 and 212 output from the controller 50 of the liquid feed pump 1 is shown in the dotted line balloon of FIG. The horizontal axis represents time, and the vertical axis represents the rotational speed. As can be seen from this graph, the rotational speed of the first motor is pulsated, and the speed of the second motor is kept constant.

  FIG. 2 is a graph showing temporal changes in the displacement of each plunger, the pressure and flow rate of each plunger pump, and the state of the solenoid valve according to the first embodiment, and the operation method of the liquid feeding pump 1 will be described using this graph. . The horizontal axis in FIG. 2 is time, the vertical axis is from the top, the displacement of the first plunger 2, the displacement of the second plunger 3, the detected pressure of the pressure sensor 105, which is the pressure of the first plunger pump 101, the second The pressure detected by the pressure sensor 60, which is the pressure of the plunger pump 102, the flow rate of the first plunger pump 101, the flow rate of the second plunger pump 102, and the total flow rate passing through the second discharge passage 11 (that is, the liquid feed pump Discharge flow rate), the state of the electromagnetic valve 81, and the state of the electromagnetic valve 82.

  The displacement of the plunger was positive in the right direction in FIG. 1, and the flow rate of the plunger pump was positive for discharge and negative for suction. Hereinafter, the movement of the plunger in the positive direction (right direction in FIG. 1) is referred to as a compression operation, and the movement in the negative direction (left direction in FIG. 1) is referred to as a suction operation.

  The operation state will be described below. During the suction operation of the first plunger 2, the second plunger 3 performs a compression operation (section 1). At this time, the check valve 4 is open and the check valve 5 is closed, so that only the second plunger 3 contributes to the solvent supply to the separation column 54. That is, when the flow rate of the second plunger pump 102 is Q [mL / s (milliliter per second)], the flow rate discharged from the liquid feed pump 1 is Q [mL / s]. At this time, the solvent sucked by the first plunger pump 101 is switched from the solvent 511 to the solvent 512 by alternately opening and closing the solenoid valve 81 and the solenoid valve 82.

  Thereafter, the first plunger 2 finishes the suction operation and starts the compression operation (section 2). At this time, both the check valve 4 and the check valve 5 are closed, the flow rate of the first plunger pump 2 is 0, and the pressure in the first pressurizing chamber 12 increases. Therefore, as in the suction operation of the first plunger 2, only the second plunger 3 contributes to the solvent feeding to the separation column 54.

  Thereafter, when the pressure of the first plunger pump 101 becomes equal to the pressure of the second plunger pump 102, the second plunger 3 ends the compression operation and starts the suction operation, and the first plunger 2 compresses. The operation is started (section 3). At this time, the check valve 4 is closed and the check valve 5 is opened, a part of the flow rate discharged from the first plunger pump 101 is sucked into the second plunger pump 102, and the rest is the liquid feed pump 1. Discharged as a flow rate.

  Therefore, the flow rate discharged from the first plunger pump 101 is controlled to be larger by Q [mL / s] than the flow rate sucked by the second plunger pump 102, and the discharge flow rate of the liquid feed pump 1 is set to Q [mL. / S].

  Thereafter, the first plunger 2 again starts the suction operation, the second plunger 3 starts the compression operation, and repeats the same operation as described above.

  In the above operation, the suction operation of the first plunger 2 in the section 1 does not affect the flow rate discharged from the liquid feed pump 1, and therefore suction can be performed at an arbitrary flow rate. Therefore, by pulsating the flow rate as shown in FIG. 2, it is possible to pulsate the flow rate of the solvent flowing through the liquid mixer 92 while keeping the discharge flow rate of the liquid feed pump 1 substantially constant.

  At this time, the flow rates flowing through the injector 53, the separation column 54 and the detector 55 are substantially constant, and the pulsation of the flow rate of the solvent flowing through the liquid mixer 92 does not affect the detector 55. On the other hand, since the flow rate pulsates in the liquid mixer 92, the liquid mixing effect in the flow direction is greater than in the case where the flow rate is constant. Thereby, the uniformity of the solvents 511 and 512 is increased, and the detection sensitivity at the detector 55 is improved.

  FIG. 3 is a graph showing a time change graph of the moving speed of the plunger according to the embodiment of the present invention. Specifically, the time change of the moving speed of the 1st plunger 2 and the 2nd plunger 3 which implement | achieves the displacement of each plunger of FIG. 2, and the flow volume of each plunger pump is shown. The flow rate Q [mL / s] of the plunger pump is obtained by the product of the plunger operating speed V [cm / s] and the plunger sectional area S [cm2]. That is, in FIG. 2, in order to pulsate the flow rate in the section 1 of the first plunger pump 101, the moving speed of the first plunger 2 in the section 1 may be pulsated. Also, the operating speed V [cm / s] of the plunger is a product of the conversion rate L [mm / rad] of the linear motion device, the reduction ratio a [−] of the reduction gear, and the rotational speed f [rad / s] of the motor. Calculated. Therefore, when the conversion rate L [mm / rad] of the linear motion device and the reduction ratio a [-] of the speed reducer are constant, the rotational speed f [rad / s] of the motor is controlled, and the moving speed of the plunger Change.

  In FIG. 3, in the section 1, the first plunger 2 moves in the negative direction while pulsating (suction operation), and the second plunger 3 moves in the positive direction at a constant speed (compression operation). In section 2, the first plunger 2 moves in the positive direction (compression operation), and the second plunger 3 moves in the positive direction at a constant speed (compression operation). In section 3, the first plunger 2 moves in the positive direction (compression operation), and the second plunger 3 moves in the negative direction (suction operation).

  4 and 5 are diagrams showing another example of the change over time of the moving speed of the plunger according to the embodiment of the present invention. As the shape of the pulsation of the plunger speed, an example of a triangular wave is shown in FIG. 3, but various shapes such as a sine wave shape shown in FIG. 4 and a rectangular wave shown in FIG.

  In the case of a triangular wave or a sine wave, the plunger speed can be continuously changed. At the time of acceleration / deceleration of the motor, inertia torque corresponding to the acceleration is applied as a load on the motor. Therefore, if the inertia torque generated when the motor speed is suddenly changed approaches the maximum output torque of the motor, the motor may step out and the plunger may not be driven. When the plunger speed is continuously changed, the inertia load is reduced, and the possibility of motor step-out is reduced. Since the speed of the sine wave changes smoothly compared to the triangular wave, the possibility of motor step-out is further reduced. In the pulsation of the triangular wave, the inclination of the plunger speed, that is, the acceleration of the plunger may be different when the speed is decreasing and increasing. The sine wave shape is strictly a sine wave shape, and the plunger speed does not need to change, and the speed may change smoothly.

  On the other hand, when the change in the plunger speed is a rectangular wave, since there are two types of speeds, the motor control is simpler than the triangular wave or the limit wave. Therefore, the processing capacity of the CPU mounted on the controller can be reduced.

3, 4 and 5, the maximum value of the plunger speed is 0, but it may be 0 or less.
In this case, since the amount of change in the plunger speed is small, the motor is easily driven. Here, the magnitude of the pulsation given to the flow rate is preferably within a range in which the plunger can reciprocate a plurality of times per unit time and the liquid can be sufficiently sucked.

  FIG. 6 is a graph showing a time change graph of the moving speed of the plunger according to the embodiment of the present invention. Specifically, the case where the speed in the section 1 of the first plunger 2 is changed for each plunger operation cycle is shown. As described above, even if the speed of the first plunger 2 in the same cycle, that is, the suction flow rate of the first plunger pump 101 is the same, when considering the cycle, the flow rate of the liquid mixer 92 is pulsated. Can be given. 7 to 9 are examples of configuration diagrams of the liquid mixer according to the embodiment of the present invention. Even if only a pipe that is normally used without arranging a special flow path as a liquid mixer, the mixing effect in the flow direction is produced by causing the pulsation of the flow rate as described above, but the liquid mixer shown in FIGS. The effect is further improved.

  FIG. 7 shows the configuration of the liquid mixer 92. Here, the dotted balloons 701, 702, 703, and 704 are schematic diagrams showing the distribution of the solvent in the flow path. The liquid mixer 92 includes a phase shift unit 921, a radial direction mixing unit 922, a flow direction mixing unit 923, and connecting flow paths 924 and 925 that connect them. In the phase shift unit 921, the inlet flow channel 9211 is branched into two branch flow channels 9212 and 9213 having different liquid passage times, and merges with the merge flow channel 9214 downstream thereof. When a liquid having a non-uniform concentration of wavelength L and period T is sent to the liquid mixer 92 in the flow direction, and the difference in passage time between the branch flow paths 9212 and 9213 is T / 2, the connection downstream of the phase shift unit In the flow path 924, the concentration unevenness in the flow direction of the liquid that has passed through the branch flow path 9213 and the liquid that has passed through the branch flow path 9212 is shifted by a half wavelength L / 2 in the flow direction. Thereafter, the liquid that has passed through the phase shift unit is mixed in the radial direction in the radial direction mixing unit, so that the concentration unevenness wavelength in the flow direction in the connection channel 925 downstream of the radial direction mixing unit becomes L / 2. That is, since the mixing distance in the flow direction is halved compared to the upstream of the liquid mixer 92, the flow direction mixing unit 923 easily mixes in the flow direction due to flow rate pulsation.

  The radial mixing unit 922 can promote mixing of the liquid in the radial direction by a configuration in which the flow is agitated by filling particles inside the flow channel, a configuration in which branching into a plurality of flow channels or subsequent merging is repeated. . However, for example, when the flow path width is sufficiently narrow, the liquid is sufficiently confused by concentration diffusion, and therefore it is not always necessary to provide a flow path having a special configuration as the radial mixing portion.

  In addition, the flow direction mixing unit 923 is configured to generate stagnation of the flow by repeatedly reducing and expanding the flow path diameter, for example, and can mix the liquid in the flow direction by changing the size of the stagnation by the pulsation of the flow rate. it can. However, downstream of the liquid mixer 92, there are portions where the diameter of the flow path changes, such as a connection portion between the liquid mixer 92 and the suction passage 10 and a connection portion between the suction passage 10 and the check valve 4. Therefore, the mixing effect can be obtained even if the flow direction mixing section 923 is not provided with a specially configured flow path.

  FIG. 8 shows an example of the configuration of the phase shift unit in the liquid mixer. Here, in the dotted balloons 801 and 802, a schematic diagram of the distribution of the solvent in the flow path is shown. The inlet channel 9211 branches into a plurality of branch channels having different liquid passage times, and merges with the merge channel 9214 downstream thereof. In FIG. 8, the structure which consists of four branch flow paths 9212, 9215, 9216, 9217 is shown. At this time, when the passage times of the adjacent branch flow paths are different by T / n (n is the number of branch flow paths), the liquid that has passed through the phase shift unit is mixed in the radial direction in the radial mixing unit, so that the diameter The concentration unevenness wavelength in the flow direction downstream of the directional mixing unit is reduced to L / n.

  With this configuration, the concentration unevenness period in the flow direction can be shortened compared to the phase shift unit configured by the two branch flow paths illustrated in FIG. 7, and the flow direction due to the flow rate pulsation in the flow direction mixing unit 923 The mixing effect of increases.

FIG. 9 shows another example of the configuration of the phase shift unit in the liquid mixer. Here, in the dotted balloons 901, 902, and 903, a schematic diagram of the distribution of the solvent in the flow path is shown. After the inlet channel 9211 branches into two branch channels 9212 and 9213 having different transit times, a plurality of channel sets 9218 configured to merge with the merge channel 9214 are connected in series. FIG. 9 shows a configuration in which two sets 9218a and 9218b are connected. When n groups are connected, when the difference in the passage time of the m-th branch channel from the upstream is T / 2 ^m (2 ^m is 2 to the power of m), the liquid that has passed through the phase shift unit 921 Is mixed in the radial direction in the radial direction mixing portion 922, so that the concentration unevenness wavelength in the flow direction downstream of the radial direction mixing portion is reduced to L / ²ⁿ .

  With this configuration, the concentration unevenness period in the flow direction can be shortened compared to the phase shift unit configured by the two branch flow paths illustrated in FIG. 7, and the flow direction due to the flow rate pulsation in the flow direction mixing unit 923 The mixing effect of increases.

The period of the pulsation of the plunger speed is preferably equal to, or k times or 1 / k times (k is a natural number), the mixing effect is high. The concentration unevenness cycle in the solvent flow direction coincides with the operation cycle of the solenoid valve. That is, it is preferable to set the operation cycle of the first plunger 2 in the section 1 shown in FIG. 3 to k times or 1 times the operation cycle of the electromagnetic valves 81 and 82 shown in FIG.

  In this embodiment, a liquid using a liquid feed pump in which a first plunger pump and a second plunger pump are arranged in series, and a liquid mixer is arranged between the first plunger pump and the second plunger pump. An example of a chromatograph will be described.

  FIG. 10 is a diagram illustrating the configuration of the liquid chromatograph according to the second embodiment. In the liquid chromatograph of FIG. 10, the description of the components having the same functions as those already described with reference to FIG. 1 is omitted. The first plunger pump 101, the liquid mixer 92, and the second plunger pump 102 are connected by connecting flow paths 241 and 242, respectively.

  FIG. 11 is a graph showing temporal changes in the displacement, pressure, flow rate, and electromagnetic valve state of each plunger according to the second embodiment. The operation method of the liquid feed pump 601 will be described with reference to FIG. In the graph of FIG. 11, the description of the same operation state portion shown in FIG.

  The operation state will be described below. In the section 1 in which the first plunger 2 performs the suction operation and the second plunger 3 performs the compression operation, the flow rate of the first plunger pump 101 is constant.

  The second plunger 3 performs the suction operation, and the first plunger 2 is driven so that the flow rate of the first plunger pump 101 pulsates in the section 3 in which the first plunger 2 performs the compression operation. Further, the second plunger 3 is driven so that the discharge flow rate of the liquid feeding pump 1, which is the sum of the flow rate of the first plunger pump 101 and the flow rate of the second plunger pump 102, is maintained at Q [mL / s]. To do.

  With this operation, it is possible to pulsate the flow rate of the solvent flowing through the liquid mixer 92 while keeping the discharge flow rate of the liquid feed pump 601 substantially constant. At this time, the flow rates flowing through the injector 53, the separation column 54, and the detector 55 are substantially constant, and the pulsation of the suction flow rate does not affect the data detected by the detector 55. On the other hand, since the flow rate pulsates in the liquid mixer 92 arranged on the suction side of the liquid feed pump 1, the liquid mixing effect in the flow direction is greater than when the suction flow rate is constant. Thereby, the uniformity of the solvents 511 and 512 is increased, and the detection sensitivity at the detector 55 is improved.

  Moreover, even if the waveform (FIGS. 3-6) of the plunger speed shown in Example 1 is applied to the speeds of the first plunger 2 and the second plunger 3 in the section 3 of this example, Similar effects can be obtained.

  Further, even when the liquid mixer (FIGS. 7 to 9) having the configuration shown in the first embodiment is applied to the liquid feed pump 601 having the configuration shown in the present embodiment, the same effect as that of the first embodiment can be obtained. .

In the first embodiment, since the liquid mixer 92 is disposed on the suction side of the first plunger pump 101, the pressure loss of the liquid mixer 92 cannot be reduced below atmospheric pressure, and the flow path of the liquid mixer 92 There are restrictions on the shape. On the other hand, in this embodiment, since the liquid mixer 92 is disposed on the discharge side of the first plunger pump 101, the pressure loss of the liquid mixer 92 can be increased. Therefore, the degree of freedom of the flow channel shape of the liquid mixer 92 is higher than that of the first embodiment, and the mixing efficiency can be further improved.

  In the present embodiment, an example of a liquid chromatograph using a liquid feed pump in which a first plunger pump and a second plunger pump are arranged in parallel will be described.

  FIG. 12 shows the configuration of a liquid chromatograph according to the third embodiment. In the liquid chromatograph of FIG. 12, the description of the components having the same functions as those already described with reference to FIG. 1 is omitted.

  The suction passage from the liquid mixer 92 to the pump branches into a first suction passage 10 and a second suction passage 104, and is connected to the first plunger pump 101 and the second plunger pump 102, respectively. The first discharge passage 103 and the second discharge passage 11 are connected to the downstream side of the second plunger pump 102, and the liquid compressed by the first plunger pump 101 and the second plunger pump 102. Are joined at the connecting portion of the first discharge passage 103 and the second discharge passage 11 and head toward the separation column 54. The first plunger pump 101 is provided with a check valve 4 in the first suction passage 10 and a check valve 5 in the first discharge passage 103, and the second plunger pump 102 has a second suction. A check valve 107 is provided in the passage 104, and a check valve 108 is provided in the second discharge passage 11. Since the operation of the first plunger pump 101 and the operation of the second plunger pump 102 are independently controlled by the controller 50 and the motor driver 106, each plunger pump can independently compress the liquid. it can.

  In the embodiment shown in FIG. 1, the example in which the pressure sensor 60 is provided in the second discharge passage 11 is shown, but it may be provided in the pressurizing chamber as shown in FIG. 12. That is, the pressure sensor 105 is provided in the first pressurizing chamber 12 of the first plunger pump 101, and the pressure sensor 60 is provided in the second pressurizing chamber 13 of the second plunger pump 102. With such a configuration, the volume of the pressure sensor 60 can be excluded from the volume of the entire flow path.

  FIG. 13 shows a graph of the time variation of the displacement, pressure, flow rate, and electromagnetic valve state of each plunger according to the third embodiment. The operation method of the liquid feed pump 801 will be described with reference to FIG. In the graph of FIG. 13, the description of the same operation state portion shown in FIG.

During the suction operation of the first plunger 2, the second plunger 3 performs a compression operation (section 1).
At this time, the check valve 4 is open and the check valve 5 is closed. In addition, the check valve 107 is closed and the check valve 108 is opened, and only the second plunger 3 contributes to the solvent feeding to the separation column 54. At this time, since the suction operation of the first plunger 2 does not affect the flow rate of the liquid feed pump 801, the suction can be performed at an arbitrary flow rate, and the flow rate can be pulsated.
At this time, the solvent that the first plunger pump 101 sucks is switched by alternately opening and closing the solenoid valve 81 and the solenoid valve 82.

  Thereafter, the first plunger 2 finishes the suction operation and starts the compression operation (section 2). At this time, both the check valve 4 and the check valve 5 are closed, and only the second plunger contributes to the liquid feeding of the solvent to the separation column 54 as in the suction operation of the first plunger 2.

  Thereafter, when the pressure of the first plunger pump 101 becomes equal to the pressure of the second plunger pump 102, the second plunger 3 ends the compression operation and starts the suction operation, and the first plunger 2 compresses. The operation is started (section 3). At this time, the check valve 107 is open and the check valve 108 is closed. In addition, the check valve 4 is closed and the check valve 5 is open, and only the first plunger 2 contributes to the solvent supply to the separation column 54. At this time, the suction operation of the second plunger 3 does not affect the flow rate of the liquid feed pump 801, so that suction can be performed at an arbitrary flow rate, and the flow rate can be pulsated. At this time, the solvent that the second plunger pump 102 sucks is switched by alternately opening and closing the electromagnetic valve 81 and the electromagnetic valve 82.

  Thereafter, the second plunger 2 finishes the suction operation and starts the compression operation (section 4). At this time, both the check valve 107 and the check valve 108 are closed, and only the first plunger 2 contributes to the liquid feeding of the solvent to the separation column 54 as in the suction operation of the second plunger 3.

  Thereafter, when the pressure of the second plunger pump 102 becomes equal to the pressure of the first plunger pump 101, the first plunger 2 starts the suction operation again, and the second plunger 3 starts the compression operation again. The same operation as above is repeated.

  By the above operation, it is possible to pulsate the flow rate of the solvent flowing through the liquid mixer 92 while keeping the discharge flow rate of the liquid feed pump 801 substantially constant. At this time, the flow rates flowing through the injector 53, the separation column 54 and the detector 55 are substantially constant, and the pulsation of the flow rate of the solvent flowing through the liquid mixer 92 does not affect the detector 55. On the other hand, since the flow rate pulsates in the liquid mixer 92, the liquid mixing effect in the flow direction is greater than in the case where the flow rate is constant. Thereby, the uniformity of the solvents 511 and 512 is increased, and the detection sensitivity at the detector 55 is improved.

  Moreover, even if the waveform (FIGS. 3 to 6) of the plunger speed shown in the first embodiment is applied to the speed of the first plunger 2 in the section 1 and the second plunger 3 in the section 3, The same effect as in the first embodiment can be obtained.

  Further, even when the liquid mixer (FIGS. 3, 4, and 5) having the configuration shown in the first embodiment is applied to the liquid feeding pump 801 having the configuration shown in the present embodiment, the same effect as that of the first embodiment can be obtained. Can do.

In Example 1, the maximum flow rate of the first plunger pump 101 is larger than the discharge flow rate of the liquid feed pump. In contrast, in this embodiment, the discharge flow rate of the second plunger pump 101 is equal to the discharge flow rate of the liquid feed pump. Therefore, the maximum output torque of the motor can be reduced in this embodiment.

  In the present embodiment, an example of a liquid chromatograph using a liquid feed pump capable of controlling the reduction ratio of the reduction gear will be described.

  FIG. 14 shows the configuration of a liquid chromatograph apparatus according to Embodiment 4 of the present invention. In the liquid chromatograph of FIG. 14, the description of the components having the same functions as those already described with reference to FIG. 1 is omitted.

The controller 50 gives a command value to the reduction gear driver 109 together with the motor driver 106 and the electromagnetic valve driver 107 based on the signals from the pressure sensors 60 and 105.
The reduction gear driver 109 supplies drive power to the reduction gears 221 and 222 based on the command value of the controller 50. By changing the reduction ratio of the reduction gears 221 and 222 based on the command value of the controller, the plunger speed can be changed even if the rotation speed of the electric motor is constant. By this method, the flow rate of each plunger pump shown in Examples 1 to 3 can be realized.

  In this embodiment, since the rotation speed of the motor is constant, the inertia load of the motor is constant. Therefore, since the motor load is reduced as compared with the first to third embodiments in which the reduction gear ratios of the reduction gears 221 and 222 are constant, the maximum load torque of the motor can be reduced.

  Needless to say, the present invention is not limited to the above-described embodiments and includes various modifications.

  Each of the above-described configurations, functions, processing units, processing means, and the like may be realized by hardware by designing a part or all of them with, for example, an integrated circuit. Each of the above-described configurations, functions, and the like may be realized by software by interpreting and executing a program that realizes each function by the processor. Information such as programs, tables, and files for realizing each function can be stored in a recording device such as a memory, a hard disk, an SSD (Solid State Drive), or a recording medium such as an IC card, an SD card, or a DVD.

The control lines and information lines indicate what is considered necessary for the explanation, and do not necessarily indicate all control lines and information lines on the product.

DESCRIPTION OF SYMBOLS 1, 1001, 1201 ... Liquid feed pump 2 ... 1st plunger 3 ... 2nd plunger 4, 5, 107, 108 ... Check valve 10 ... 1st suction passage 11 ... second discharge passage 12 ... first pressurizing chamber 13 ... second pressurizing chamber 50 ... controller 53 ... injector 54 ... separation column 55 ... detector 60, 105 ... pressure sensors 61, 62 ... seals 71, 72 ... bearings 81, 82 ... solenoid valve 91 ... confluence 92 ... liquid mixer 101 ... first Plunger pump 102 ... second plunger pump 103 ... first discharge passage 104 ... second suction passage 106 ... motor driver 107 ... solenoid valve driver 211 ... first electric motor Motor 212... Second electric motor 221, 222. Decelerators 231, 232... Linear motion devices 511, 512... Solvents 701, 702, 703, 704, 801, 802, 901, 902, 903. ..Branch channel phase shift unit 922... Radial direction mixing unit 923... Flow direction mixing units 924 and 925... Connection channel 9211. ... Confluence channel

Claims (13)

A first pump unit comprising: a first pressurizing chamber having a first suction passage and a first discharge passage; and a first plunger reciprocating in the first pressurizing chamber;
A second pump unit comprising: a second pressurizing chamber having a second suction passage and a second discharge passage; and a second plunger that reciprocates in the second pressurizing chamber;
A connection channel connecting the said first pump unit the second pump unit,
A drive unit for driving the first and second plungers;
A pressure detector that detects the pressure of fluid discharged from at least one of the first and second pump units;
Valve means for switching a plurality of liquids sucked by the first pump unit;
A merging portion where the plurality of sucked liquids merge,
A mixing section for mixing the merged liquid ;
Before Kiben means, the feeding device and a control unit for controlling the drive unit,
The controller is
While maintaining a constant flow rate of the liquid passing through the discharge flow path of the second pump unit,
To pulsate the liquid that has passed through the junction,
A liquid feeding device that controls the driving unit. In the liquid feeding device described in claim 1,
The controller is
While the first plunger is performing a suction operation,
While pulsating the flow rate of the liquid sucked into the first pressurizing chamber,
The second plunger performs a compression operation and keeps the flow rate of the liquid discharged from the second pressurizing chamber constant.
A liquid feeding device that controls the driving unit. In the liquid feeding device described in claim 1,
The mixing unit is disposed between the first pump unit and the second pump unit,
The controller is
While the first plunger performs the compression operation, the flow rate of the liquid discharged from the first pressurizing chamber is pulsated,
The second plunger performs a suction operation and pulsates the flow rate of the liquid sucked into the second pressurizing chamber,
While the pulsation occurs, the first plunger is sucked into the second pressurizing chamber based on the flow rate of the liquid discharged from the first pressurizing chamber and the operation of the second plunger. In order to keep the sum of the liquid flow rate and a constant value,
A liquid feeding device that controls the driving unit. In the liquid feeding device described in claim 1,
The controller is
While the first plunger performs the suction operation, the flow rate of the liquid sucked into the first pressurizing chamber is pulsated,
A first state in which the second plunger performs a compression operation and the flow rate of the liquid discharged from the second pressurizing chamber is kept constant;
While the first plunger performs the compression operation, the flow rate of the liquid discharged from the first pressurizing chamber is kept constant,
A second state in which the second plunger performs a suction operation and pulsates the flow rate of the liquid sucked into the second pressurizing chamber;
An apparatus for controlling the operation of the driving unit and the valve means. In the liquid feeding device described in claim 1,
The mixing unit further includes:
A liquid delivery device having a structure branched into a plurality of flow paths having different lengths. In the liquid feeding device described in claim 1,
The mixing unit further includes:
A liquid feeding apparatus comprising a plurality of units each composed of a branch channel branched into a plurality of channels having different lengths, wherein the plurality of units are connected in series. A first pump unit comprising: a first pressurizing chamber having a first suction passage and a first discharge passage; and a first plunger reciprocating in the first pressurizing chamber;
A second pump unit comprising: a second pressurizing chamber having a second suction passage and a second discharge passage; and a second plunger that reciprocates in the second pressurizing chamber;
A connection channel connecting the said first pump unit the second pump unit,
A drive unit for driving the first and second plungers;
A pressure detector that detects the pressure of fluid discharged from at least one of the first and second pump units;
Valve means for switching a plurality of liquids sucked by the first pump unit;
A merging portion where the plurality of sucked liquids merge,
A mixing section for mixing the merged liquid ;
In the liquid chromatograph device and a control device for controlling the front SL driver,
The controller is
While maintaining a constant flow rate of the liquid passing through the discharge flow path of the second pump unit,
To pulsate the liquid that has passed through the junction,
A liquid chromatograph apparatus that controls the drive unit. In the liquid chromatograph apparatus described in Claim 7,
The controller is
While the first plunger is performing a suction operation,
While pulsating the flow rate of the liquid sucked into the first pressurizing chamber,
The second plunger performs a compression operation and keeps the flow rate of the liquid discharged from the second pressurizing chamber constant.
A liquid chromatograph apparatus that controls the drive unit. In the liquid chromatograph apparatus described in Claim 7,
The mixing unit is disposed between the first pump unit and the second pump unit,
The controller is
While the first plunger performs the compression operation, the flow rate of the liquid discharged from the first pressurizing chamber is pulsated,
The second plunger performs a suction operation and pulsates the flow rate of the liquid sucked into the second pressurizing chamber,
While the pulsation occurs, the first plunger is sucked into the second pressurizing chamber based on the flow rate of the liquid discharged from the first pressurizing chamber and the operation of the second plunger. In order to keep the sum of the liquid flow rate and a constant value,
A liquid chromatograph apparatus that controls the drive unit. In the liquid chromatograph apparatus described in Claim 7,
The controller is
While the first plunger performs the suction operation, the flow rate of the liquid sucked into the first pressurizing chamber is pulsated,
A first state in which the second plunger performs a compression operation and the flow rate of the liquid discharged from the second pressurizing chamber is kept constant;
While the first plunger performs the compression operation, the flow rate of the liquid discharged from the first pressurizing chamber is kept constant,
A second state in which the second plunger performs a suction operation and pulsates the flow rate of the liquid sucked into the second pressurizing chamber;
A liquid chromatograph apparatus for controlling operations of the driving unit and the valve means. In the liquid chromatograph apparatus described in Claim 7,
The mixing unit further includes:
A liquid chromatograph having a structure branched into a plurality of flow paths having different lengths. In the liquid chromatograph apparatus described in Claim 7,
The mixing unit further includes:
A liquid chromatograph apparatus comprising a plurality of units each composed of a branch channel branched into a plurality of channels having different lengths, wherein the plurality of units are connected in series. In the liquid feeding method of the liquid chromatograph in which different types of liquid are sucked and discharged through the first pump unit and the second pump unit, and sent to the analyzer,
Switching the type of the liquid to be sucked by opening and closing the valve means;
Mixing each liquid after being sucked through a mixing section;
Feeding the mixed liquid from the first pump unit to the second pump unit;
The second pump unit sucks the liquid sent from the first pump unit and sends the liquid to the analyzer;
While maintaining a constant flow rate discharged from the second pump unit, and pulsating the liquid that has passed through the mixing unit,
And a step of controlling the operations of the first and second pump units.