JP3165325U - Syringe pump and total organic carbon meter including the same - Google Patents

Abstract

A syringe pump capable of sufficiently sealing between a cylindrical body and a lid is provided. A syringe 31 provided with a glass cylindrical body 32, a metal lid 33, and a syringe head 34, and a syringe inserted from the opening on the distal end side of the cylindrical body 32 of the syringe 31. And a plunger 41, which is a columnar body that can reciprocate within the cylindrical body 32, and the lid body 33 is formed with a cylindrical portion having openings at the upper end and the end. The syringe head 34 is inserted through the opening on the distal end side of the cylindrical portion of the lid 33, and a protruding portion is formed so as to protrude from the opening on the distal end side. A syringe pump 30 is configured by forming a through-hole for circulating the liquid. Further, the syringe head 34 is formed of polytetrafluoroethylene that is crushed by applying a load in a direction from the opening on the distal end side of the cylindrical portion of the lid 33 toward the opening on the distal end. [Selection] Figure 1

Description

  The present invention relates to a syringe pump used in a total organic carbon meter (TOC meter) for measuring a TOC (total organic carbon) concentration in a solution sample and a total organic carbon meter including the syringe pump.

In recent years, measurement of organic carbon concentration in water such as water and sewage water, water for various plants, and rivers has become one of the important items for pollution investigations. A total organic carbon meter (TOC meter) is used for measuring the organic carbon concentration.
The total organic carbon meter mainly measures the total organic carbon concentration by burning an aqueous solution sample from which inorganic carbon (IC) has been removed in advance by bubbling or the like in a combustion tube and measuring the generated carbon dioxide, A method is known in which an aqueous sample is burned and the total organic carbon concentration is measured by subtracting the measured value of inorganic carbon separately measured from the measured value of total carbon (TC).

FIG. 3 is an overall schematic diagram showing an example of the total organic carbon meter.
The total organic carbon meter 101 includes a multiport valve 20, a microsyringe pump 130, a motor (driving mechanism) M2 that drives the plunger 41 of the microsyringe pump 130, and a motor (driving mechanism) M1 that drives the multiport valve. And a measurement unit 10 that converts all organic carbon components in the aqueous solution sample into carbon dioxide (see, for example, Patent Document 1).

The multiport valve 20 includes a common port 2z and four distribution ports 2a to 2d. The multi-port valve 20 is driven by the motor M1, and selectively connects the common port 2z and the one distribution port 2a to 2d.
A sample channel 5 is connected to the distribution port 2b. Thereby, the common port 2z and the distribution port 2b are connected and the aqueous solution sample to be measured is sucked into the microsyringe pump 130 from the distribution port 2b when the plunger 41 moves downward. An acid container is connected to the distribution port 2c through an acid inflow pipe 6. As a result, the acid used for bubbling is sucked from the distribution port 2c to the microsyringe pump 130 when the common port 2z and the distribution port 2c are connected and the plunger 41 moves downward. Further, a drain is connected to the distribution port 2d through a drain pipe 4d. Accordingly, the inorganic carbon component (carbon dioxide) released by bubbling is discharged from the distribution port 2d when the common port 2z and the distribution port 2d are connected and the plunger 41 moves upward. Furthermore, a TC sample injection unit 7 is connected to the distribution port 2a via a sample injection tube 4a. As a result, the bubbled aqueous solution sample is connected to the common port 2z and the distribution port 2a, and is injected into the TC combustion unit 8 from the distribution port 2a when the plunger 41 moves upward.

  The TC sample injection unit 7 injects the bubbling aqueous solution sample sent from the microsyringe pump 130 into the TC combustion unit 8 together with the carrier gas. The TC combustion unit 8 burns the injected aqueous solution sample and converts all organic carbon components in the aqueous solution sample into carbon dioxide. The combustion gas generated by the combustion in the TC combustion unit 8 is sent to a CO2 detection unit such as an infrared gas analyzer, and the total organic carbon concentration in the aqueous solution sample is measured from the amount of carbon dioxide in the combustion gas.

Here, in order to accurately measure the total organic carbon concentration in the total organic carbon meter 101, it is necessary to pour a desired amount of the aqueous solution sample into the measuring unit 10 with extremely high accuracy. The micro syringe pump 130 is connected to the port 2z.
FIG. 4 is a diagram illustrating an example of a conventional microsyringe pump 130. FIG. 5 is an enlarged cross-sectional view of the tip of the microsyringe pump 130 shown in FIG.
The micro syringe pump 130 includes a syringe 131 and a plunger 41.
The syringe 131 includes a glass cylindrical body 32, a metal lid 33, and polychlorotrifluoroethylene (trade name “Daiflon (registered trademark)) disposed between the cylindrical body 32 and the lid 33. PCTFE "etc.).

The cylindrical body 32 has a cylindrical shape and has circular openings 32a and 32b at upper and lower ends.
The lid 33 has a first cylindrical portion 33a having a cylindrical shape and a second cylindrical portion 33b having a cylindrical shape. The inner diameter of the second cylindrical portion 33 b is larger than the outer diameter of the first cylindrical portion 33 a and is formed to match the outer diameter of the cylindrical body 32. Accordingly, the inner diameter of the second cylindrical portion 33 b is fitted to the outer diameter of the opening 32 a of the cylindrical body 32. In addition, the screw mechanism 33c for connecting with the multiport valve 20 is formed in the outer peripheral surface of the 1st cylindrical part 33a.

The syringe head 134 integrally has a cylindrical first cylindrical portion 134a, a cylindrical second cylindrical portion 134b, and a cylindrical third cylindrical portion 134c in this order from the top. The outer diameter of the first cylindrical portion 134a is formed so as to coincide with the inner diameter of the first cylindrical portion 33a. Further, the outer diameter of the second cylindrical portion 134b is formed to be slightly smaller than the inner diameter of the second cylindrical portion 33b. Further, the outer diameter of the third cylindrical portion 134 c is formed so as to coincide with the inner diameter of the cylindrical body 32. Accordingly, the syringe head 134 is arranged between the opening 32 a of the cylindrical body 32 and the lid body 33. At this time, the 1st cylindrical part 134a is inserted from the opening part of the lower end side (terminal side) of the 1st cylindrical part 33a, and about 0.8 mm-1 .. It arrange | positions so that 2 mm may protrude.
The first cylindrical portion 134a, the second cylindrical portion 134b, and the third cylindrical portion 134c are formed with through holes 134d for allowing the aqueous solution sample to flow in the vertical direction.

  The plunger 41 is a columnar body that is inserted from the opening 32 b of the cylindrical body 32 of the syringe 131 and can reciprocate in the vertical direction inside the cylindrical body 32. The plunger 41 is driven by the motor M2.

Here, FIG. 6 is a detailed sectional view showing an example of the multiport valve 20.
The multiport valve 20 includes a cylindrical metal fixed block 21 and a columnar metal rotary block 22 formed in close contact with the fixed block 21 so as to be rotatable about a shaft 22a.

  Distribution ports 2a to 2d (distribution ports 2c and 2d are not shown) are formed on the side wall of the fixed block 21, and a common port 2z is formed on the bottom surface. The rotating block 22 is formed with an L-shaped conduit 23 for selectively connecting the common port 2z and the one distribution port 2a to 2d. As a result, the common port 2z is connected to any of the distribution ports 2a to 2d connected via the pipe line 23, and the other non-connected distribution ports are shared by close engagement with the outer peripheral surface of the rotating block 22. The connection with the port 2z is completely cut off.

JP-A-9-43224

By the way, the micro syringe pump 130 is connected to the common port 2z of the multi-port valve 20 by the screw mechanism 33c. At this time, the upper end portion of the syringe head 134 made of polychlorotrifluoroethylene is the common port of the fixed block 21. 2z.
However, since the polychlorotrifluoroethylene forming the syringe head 134 is a hard resin, the seal between the glass cylindrical body 32 and the metal lid 33 may be insufficient.

In order to solve the above-mentioned problem, the present inventor examined the micro syringe pump 130 that can sufficiently seal the space between the cylindrical body 32 and the lid body 33. First, the 1st cylindrical part 134a, the 2nd cylindrical part 134b, and the 3rd cylindrical part 134c of the syringe head 134 were formed with the polytetrafluoroethylene which is soft resin. As a result, the space between the cylindrical body 32 and the lid body 33 could be sufficiently sealed, but creeping occurred, and the connection between the common port 2z and the microsyringe pump 130 was loosened.
Next, while forming the 1st cylindrical part 134a and the 2nd cylindrical part 134b of the syringe head 134 with polytetrafluoroethylene which is soft resin, the 3rd cylindrical part 134c is made of polychloro which is hard resin. Formed with trifluoroethylene. As a result, the space between the cylindrical body 32 and the lid body 33 can be sufficiently sealed, creep does not occur, and the connection between the common port 2z and the microsyringe pump 130 is not loosened. However, since the second cylindrical portion 134b and the third cylindrical portion 134c are bonded with an adhesive, the adhesive sometimes affects the measurement.

  Therefore, the first cylindrical portion 134a, the second cylindrical portion 134b, and the third cylindrical portion 134c of the syringe head 134 are formed of polytetrafluoroethylene, which is a soft resin, and then the first cylindrical portion 134a. The tip portion is crushed by applying a load in a direction from the opening on the upper end side of the cylindrical portion 33a of the lid 33 toward the opening on the lower end side. As a result, the syringe head 134 is not plastically deformed during use, does not cause creep, and the connection between the common port 2z and the microsyringe pump 130 is not loosened.

  That is, the syringe pump of the present invention includes a glass cylindrical body having openings at the tip and end, a metal lid disposed at the opening on the tip side, and a tip side of the cylindrical body. A syringe provided with a syringe head disposed between the opening and the lid, and a columnar shape which is inserted from the opening on the terminal side of the cylindrical body of the syringe and can reciprocate inside the cylindrical body of the syringe A plunger that is a body, and the lid is formed with a cylindrical portion having an opening at a tip and a distal end, and the syringe head is inserted from an opening on the distal side of the cylindrical portion of the lid A syringe pump formed so as to protrude from the opening on the distal end side, and a through hole for allowing a solution sample to flow therethrough is formed in the protrusion, wherein the syringe head At the tip of the protrusion In a direction towards the opening of the distal from the distal end side of the opening of Jo portion under a load it is to be formed in collapsed polytetrafluoroethylene.

  As described above, according to the syringe pump of the present invention, the space between the cylindrical body and the lid can be sufficiently sealed. Furthermore, the syringe head is not plastically deformed during use, does not cause creep, and the connection between the multiport valve and the microsyringe pump is not loosened.

(Means and effects for solving other problems)
In the syringe pump of the present invention, the syringe head may be formed of polytetrafluoroethylene crushed by applying a load of 1.1 N or more to the protruding portion.
The total organic carbon meter of the present invention includes a syringe pump as described above, a multiport valve, a drive mechanism that drives the plunger, a drive mechanism that drives the multiport valve, and an entire solution sample in the solution sample. You may make it provide the measurement part which converts an organic carbon component into a carbon dioxide.

It is a figure which shows an example of the micro syringe pump which concerns on this invention. It is an expanded sectional view of the front-end | tip part of the micro syringe pump shown in FIG. It is the whole schematic which shows an example of a total organic carbon meter. It is a figure which shows an example of the conventional micro syringe pump. It is an expanded sectional view of the front-end | tip part of the micro syringe pump shown in FIG. It is a detailed sectional view showing an example of a multiport valve.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments described below, and it goes without saying that various aspects are included without departing from the spirit of the present invention.

FIG. 1 is a view showing an example of a microsyringe pump according to the present invention. FIG. 2 is an enlarged cross-sectional view of the tip portion of the microsyringe pump shown in FIG. In addition, the same code | symbol is attached | subjected about the thing similar to the micro syringe pump 130 mentioned above.
The micro syringe pump 30 includes a syringe 31 and a plunger 41.
The syringe 31 includes a glass cylindrical body 32, a metal lid body 33, and a syringe head 34 disposed between the cylindrical body 32 and the lid body 33.

The syringe head 34 integrally includes a cylindrical first cylindrical portion 34a, a cylindrical second cylindrical portion 34b, and a cylindrical third cylindrical portion 34c in this order from the top. The outer diameter of the first cylindrical portion 34a is formed to match the inner diameter of the first cylindrical portion 33a. Further, the outer diameter of the second cylindrical portion 34b is formed to be slightly smaller than the inner diameter of the second cylindrical portion 33b. Further, the outer diameter of the third cylindrical portion 34 c is formed to match the inner diameter of the cylindrical body 32. Accordingly, the syringe head 34 is arranged between the opening 32 a of the cylindrical body 32 and the lid body 33. At this time, the upper end portion of the first cylindrical portion 34a is inserted from the lower end side (terminal side) opening portion of the first cylindrical portion 33a, and about 0.8 mm upward from the upper end side (tip end side) opening portion. It arrange | positions so that it may project -1.2mm.
The first cylindrical portion 34a, the second cylindrical portion 34b, and the third cylindrical portion 34c are formed with through holes 34d through which the aqueous solution sample flows in the vertical direction.

  Moreover, the syringe head 34 is 1.1 N in the direction (downward) toward the opening part of the lower end side from the opening part of the upper end side of the 1st cylindrical part 33a of the cover body 33 at the front-end | tip part of the 1st cylindrical part 34a. It is formed of polytetrafluoroethylene (trade name “Teflon (registered trademark)” or the like) that has been crushed under the above load (preferably 1.2 N). The polytetrafluoroethylene may be cross-linked.

Here, a micro syringe pump manufacturing method for manufacturing the micro syringe pump 30 will be described. The microsyringe pump manufacturing method includes a preparation step (A), an assembly step (B), and a pressing step (C).
(A) Preparation Step A syringe head 34 ′ made of polytetrafluoroethylene is prepared. The syringe head 34 ′ is formed by integrating a cylindrical first cylindrical portion 34a ′, a cylindrical second cylindrical portion 34b ′, and a cylindrical third cylindrical portion 34c ′ in this order from the top. Have. At this time, the syringe head 34 ′ is made of polytetrafluoroethylene that is not crushed under load.

(B) Assembly process Syringe head 34 'is attached to the cover body 33, and also the cylindrical body 32 is attached. That is, the micro syringe pump 30 ′ is assembled. At this time, the first cylindrical portion 34a is disposed so as to protrude upward by about 1.6 mm from the opening on the upper end side of the first cylindrical portion 33a of the lid 33.
(C) Pressing step The first cylindrical portion 34a ′ of the syringe head 34 ′ is set to 1 in the direction (downward) from the opening on the upper end side of the first cylindrical portion 33a of the lid 33 toward the opening on the distal side. Crush with a load of 1N or more (preferably 1.2N). Thereby, the 1st cylindrical part 34a is arrange | positioned so that it may protrude about 0.8 mm-1.2 mm upwards from the opening part of the upper end side of the 1st cylindrical part 33a.

  As described above, according to the microsyringe pump 30 of the present invention, the space between the cylindrical body 32 and the lid body 33 can be sufficiently sealed. Furthermore, the syringe head 34 is not plastically deformed during use, does not cause creep, and the connection between the multiport valve 20 and the microsyringe pump 30 is not loosened.

  The present invention can be used for a syringe pump or the like used in a total organic carbon meter that measures the TOC concentration in a solution sample.

31: Syringe 32: Cylindrical body 32a, 32b: Opening 33: Lid 33a: Cylindrical part 34: Syringe head 34a: Cylindrical part (protrusion part)
34d: Through hole 41: Plunger

Claims (3)

A glass cylindrical body having openings at the tip and end, a metal lid disposed at the opening on the tip side, and between the opening and lid on the tip side of the cylindrical body A syringe comprising a syringe head disposed;
A plunger, which is a columnar body that is inserted from the opening on the terminal side of the cylindrical body of the syringe and is capable of reciprocating inside the cylindrical body of the syringe;
The lid is formed with a cylindrical portion having openings at the tip and the end,
The syringe head is inserted from the opening on the terminal side of the cylindrical portion of the lid, and a protruding portion is formed so as to protrude from the opening on the tip side.
The protrusion is a syringe pump in which a through-hole for circulating a solution sample is formed,
The syringe head is formed of polytetrafluoroethylene crushed by applying a load in the direction from the opening on the distal end side to the opening on the distal end of the cylindrical portion of the lid at the distal end of the protrusion. A syringe pump characterized by The syringe pump according to claim 1, wherein the syringe head is formed of polytetrafluoroethylene crushed by applying a load of 1.1 N or more to the protruding portion. The syringe pump according to claim 1 or claim 2,
A multi-port valve,
A drive mechanism for driving the plunger;
A drive mechanism for driving the multi-port valve;
A total organic carbon meter comprising: a measuring unit that converts all organic carbon components in the solution sample into carbon dioxide.

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