Pipette device

Abstract

A pipette device is provided and prevents the corrosion of main metal parts without causing a significant rise in costs. A pipette device includes a piston portion that is movable in order to suck a liquid and an air hole for discharging an air generated from the liquid sucked by the piston portion to an outside. The air is discharged from the air hole in response to movement of the piston portion.

Claims

1. A pipette device, comprising: a pressing portion that is disposed on a rear end portion for a user to press; a piston rod portion that is connected to the pressing portion; a piston portion that is connected to the piston rod portion and is movable in order to suck a liquid; a case portion in which the piston rod portion is disposed and which has an air hole for discharging an air generated from the liquid sucked by the piston portion to an outside; and a piston accommodating portion configured for movably disposing the piston portion and including: a piston accommodating upper portion that has a female thread portion; a piston accommodating lower portion that has a male thread portion, wherein the piston accommodating upper portion and the piston accommodating lower portion are screwed with and fixed to each other by screwing the female thread portion with the male thread portion; and a packing portion that has an annular shape between the piston accommodating upper portion and the piston accommodating lower portion and has an annular inner portion, wherein the piston portion is disposed to be slidable in the annular inner portion of the packing portion that has the annular shape, and the air is discharged from the air hole of the case portion in response to movement of the piston portion; wherein the case portion comprises a first case portion and a second case portion engaged with each other, and the air hole is included in any one of or both of the first case portion and a second case portion; wherein a center of each of the pressing portion, the piston rod portion, the case portion, the packing portion, the piston accommodating portion, and the piston portion is disposed on the same line; along the same line, the piston accommodating lower portion, the piston accommodating upper portion, the second case portion, the first case portion are disposed in this order; and the air hole is configured to directly communicate an inside of the case portion and the outside.

2. The pipette device according to claim 1, further comprising: an elastic portion that biases the piston rod portion in a rear end portion direction.

3. The pipette device according to claim 1, further comprising: a pipette tip holding portion that is disposed in a front end portion direction of the piston accommodating portion and removably holds a pipette tip.

4. The pipette device according to claim 3, further comprising: an elastic portion that biases the piston rod portion in a rear end portion direction.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a perspective view of a pipette device.

(2) FIG. 2 is a longitudinal sectional view of the pipette device.

(3) FIG. 3 is a longitudinal section enlarged view of a case portion of the pipette device.

(4) FIG. 4a is a view illustrating a state where a second knob portion is disposed on a lower side of a second window portion, FIG. 4b is a view illustrating a state where the second knob portion is disposed in a middle of the second window portion, and FIG. 4c is a view illustrating a state where the second knob portion is disposed on an upper side of the second window portion.

(5) FIG. 5 is a longitudinal section enlarged view of the case portion of the pipette device.

(6) FIG. 6 is a longitudinal section enlarged view of a piston accommodating portion of the pipette device.

(7) FIG. 7 is a longitudinal sectional view of a knob portion disposed to the right in the pipette device.

(8) FIG. 8 is a longitudinal sectional view of the knob portion disposed to the left in the pipette device.

(9) FIG. 9 is a perspective view of a pipette device of another embodiment.

(10) FIG. 10 is a longitudinal sectional view of the pipette device of another embodiment.

DESCRIPTION OF EMBODIMENTS

(11) A pipette device 10 of the embodiment will be described. The pipette device 10 of a first embodiment has a pressing portion 20 that is disposed on a rear end portion for a user to press, a piston rod portion 30 connected to the pressing portion 20, a case portion 40 for the user to grab, a piston portion 50 that is connected to the piston rod portion 30 and is movable in order to suck a liquid, a piston accommodating portion 70 that accommodates the piston portion 50. The case portion 40 has an air hole 49 for discharging air X generated from the liquid sucked by the piston portion 50 to the outside (refer to FIGS. 1 and 2).

(12) That is, the pipette device 10 is a device in which the air hole 49 is provided in the case portion 40 for a user to grab in order to discharge the air X, which is sucked by the piston portion 50 and is generated from a liquid chemical, to the outside. Therefore, the piston portion 50 is movable in a front end portion direction F and a rear end portion direction R of the pipette device 10. In response to motion of the piston portion moving, the air X in the pipette device 10 can be discharged to the outside from the air hole 49, or fresh air can be introduced from the air hole 49. Consequently, corrosion can be prevented without making a metal part in the pipette device 10 of a material which is highly resistant to corrosion or performing surface treatment such as plating.

(13) Each configuration of the pipette device 10 will be described. The pipette device 10 has the pressing portion 20, the piston rod portion 30 connected to the pressing portion 20, the case portion 40 that accommodates a part of the piston rod portion 30 and has the air hole 49 allowing outside air to pass therethrough, the piston portion 50, a packing portion 60, and the piston accommodating portion 70. In addition, a pipette tip 80 is removably disposed. A center of each of the pressing portion 20, the piston rod portion 30, the case portion 40, the packing portion 60, the piston accommodating portion 70, and the piston portion 50 is disposed on the same line.

(14) The pressing portion 20 is literally for a user to perform an operation of pressing in order to discharge a liquid as will be described later. The pressing portion 20 has a long shaft portion 21, a disk-shaped knob portion 22 in a rear end direction R, and an uneven portion 23 having a recessed portion and a projecting portion that are disposed on an edge of the knob portion 22. As will be described later, the uneven portion 23 is provided as a slip stopper when a user rotates the shaft portion 21 about an axis. In addition, the pressing portion has a long hollow tubular portion 26, and the long shaft portion 21 is disposed inside the tubular portion 26. The shaft portion 21 is fixed such that the rotation of the shaft portion about the axis synchronizes with the rotation of the tubular portion 26 although not illustrated. When the shaft portion 21 rotates one time about the axis, also the tubular portion 26 rotates one time about the shaft portion 21.

(15) The tubular portion 26 rotates about the axis as described above. Since a female thread portion 41a is formed inside a first case portion 41 of the case portion 40, which is to be described later, and also a male thread portion 26a is formed in the tubular portion 26, the female thread portion and the male thread portion are screwed with each other in the tubular portion 26. That is, the male thread portion 26a is screwed with the female thread portion 41a. Therefore, when the shaft portion 21 rotates about the axis, also the tubular portion 26 rotates, and the shaft portion 21 relatively moves with respect to the tubular portion 26 in the front end portion direction F. When the shaft portion 21 rotates reversely, the shaft portion 21 relatively moves with respect to the tubular portion 26 in the rear end portion direction R. Accordingly, as will be described later, the piston portion 50 is moved forward in the front end portion direction F or is moved backward in the rear end portion direction R by the piston rod portion 30 connected to the shaft portion 21, and thus the piston portion can adjust an increase or decrease in the amount of a liquid to be sucked. This will be further described later.

(16) The piston rod portion 30 is disposed inside the case portion 40. In addition, the piston rod portion 30 has a piston shaft portion 31 and a thick shaft upper end portion 32. The thick shaft upper end portion 32 has a thick shaft portion 32a and an upper end portion 32b. In addition, the piston shaft portion 31 literally has a long rod shape, and is disposed such that one end of the piston shaft portion 31 is covered by the thick shaft portion 32a which is thicker than the piston shaft portion 31. That is, the thick shaft portion 32a has a hollow tubular shape, and the piston shaft portion 31 is disposed and fixed therein. In addition, the dish-shaped upper end portion 32b is fixed to an end portion of the thick shaft portion 32a. The other end of the piston shaft portion 31 in the front end portion direction F is connected to the piston portion 50 to be described later (refer to FIG. 3).

(17) An elastic portion 33 biases the piston rod portion 30 in a direction of the pressing portion 20, that is, the rear end portion direction R. In the elastic portion 33, a first spring portion 33a, a first washer portion 33c, a second washer portion 33d, and a second spring portion 33b are disposed in this order from the rear end portion direction R to an end portion direction F. The piston shaft portion 31 is inserted in all of the first spring portion, the first washer portion, the second washer portion, and the second spring portion. The piston shaft portion 31 is disposed to penetrate through a center of each of the first spring portion 33a, the first washer portion 33c, the second washer portion 33d, and the second spring portion 33b. Therefore, in this case, it is preferable that the first spring portion 33a and the second spring portion 33b be coil springs. In addition, it is preferable that the first washer portion 33c and a second washer portion 33 each have a disk shape (refer to FIG. 3).

(18) The first spring portion 33a has one end that is in contact with the thick shaft upper end portion 32 of the piston rod portion 30, and the other end portion that is in contact with the first washer portion 33c. In addition, the first washer portion 33c and the second washer portion 33d are disposed to be in contact with each other (refer to FIG. 3).

(19) In addition, the second spring portion 33b has one end that is in contact with the second washer portion 33d, and the other end that is in contact with a recessed portion 47 of a second case portion 46 to be described later. A center hole portion 33cc, which is a circular hole, is disposed in the center of the first washer portion 33c, and the center hole portion 33cc has a diameter that allows the thick shaft portion 32a to pass therethrough. A second center hole portion 33dd, which is a circular hole, is disposed in the center of second washer portion 33d, and the second center hole portion 33dd has a diameter that is smaller than the center hole portion 33cc so as not to allow the thick shaft portion 32a to pass therethrough. Therefore, the diameter of the center hole portion 33cc, a diameter of the pressing portion 20, and the diameter of the second center hole portion 33dd are set in diameter decreasing order. As described above, the piston shaft portion 31 of the piston rod portion 30 penetrates through all of the first spring portion, the first washer portion, the second washer portion, and the second spring portion. In addition, the second spring portion 33b has a spring constant higher than the first spring portion 33a.

(20) In addition, as described above, the piston shaft portion 31 is disposed to be inserted in all, that is, the first spring portion 33a, the first washer portion 33c, the second washer portion 33d, and the second spring portion 33b. Consequently, the piston rod portion 30 is biased in the rear end portion direction R by the first spring portion 33a, the first washer portion 33c, the second washer portion 33d, and the second spring portion 33b, and this serves as resistance when pressing the pressing portion 20 in the front end portion direction F. For this reason, also the piston portion 50 to be described later is biased in the rear end portion direction R.

(21) As described above, the case portion 40 has the first case portion 41 and the second case portion 46. The first case portion 41 has a hollow tubular inside, and an external shape thereof is almost a wedge shape allowing a user to grab. Therefore, the case portion 40 has a shape that allows the user to easily grasp.

(22) In addition, the first case portion 41 has a window portion 42 and a second window portion 44. A graduation portion 43 is disposed inside the window portion 42. The graduation portion 43 displays a three-digit number, and displays a movement amount of the tubular portion 26. The graduation portion 43 is configured of a transparent resin and has a hollow tubular shape. Inside the graduation portion, three stages of numbers are displayed. A lower stage 43a displays the tens' place, an interruption 43b displays the hundreds' place, and an upper stage 43c displays the thousands' place. One graduation of the lower stage 43a indicates 10, and a graduation indicating 50 is marked with one rotation. When the lower stage 43a rotates by ten graduations, a middle stage 43b rotates by one graduation. When the middle stage 43b rotates one time, the upper stage 43c rotates by one graduation. While graduations are marked from 0 to 9 in the upper stage 43c, the upper stage 43c is allowed to rotate up until a graduation of 6. This will be described later.

(23) A second knob portion 27 fixed to the tubular portion 26 is disposed on the second window portion 44. A user can increase or decrease the movement amount of the tubular portion 26 by rotating the second knob portion 27 about an axis through the second window portion 44 as in the case of rotating a knob portion 23. By the second knob portion 27 disposed on the tubular portion 26 coming into contact with a second window upper end portion 44a of the second window portion 44, the movement of the tubular portion 26 is limited, and the second knob portion 27 is set not to rotate any further. Therefore, as described above, the movement amount of the tubular portion 26 is limited such that 6 is the maximum of the tens' place (refer to FIGS. 4a, 4b, and 4c). Therefore, the movement of the pressing portion 20 which is fixed thereto is limited, and thereby the movement of the piston rod portion 30 connected to the pressing portion and the movement of the piston portion 50 are also limited.

(24) A step portion 45b is provided on an inner side of the other end portion 45a of the first case portion 41, which has a hollow tubular shape, and is disposed to be engaged with the first washer portion 33c in a case of being connected to the second case portion 46 via a connecting portion 100. Therefore, an outer diameter of the first washer portion 33c is almost the same dimension as an inner diameter of the step portion 45b such that the first washer portion can be disposed in the inner diameter (refer to FIG. 5).

(25) The second case portion 46 has a hollow tubular shape, and the piston rod portion 30 is disposed to be movable in the front end portion direction F or the rear end portion direction R in a tube hole 46a that is disposed in a center of the tubular shape. In addition, the other end of the second spring portion 33b is disposed in the recessed portion 47 as described above.

(26) In addition, although the air hole 49 can be included in any one of or both of the first case portion 41 and the second case portion 46, the air hole is provided in the other end portion 45a of the first case portion 41 in the embodiment. The air hole functions as a discharge outlet through which the air X containing a chemical solution is discharged or an introduction inlet through which fresh air is introduced.

(27) The piston accommodating portion 70 functions as a so-called piston cylinder, and has a piston accommodating upper portion 71 and a piston accommodating lower portion 72, both of which have bottomed tubular shapes. Since the piston accommodating upper portion and the piston accommodating lower portion respectively have a female thread portion 71b and a male thread portion 72b in opening portions 71a and 72a, the piston accommodating upper portion and the piston accommodating lower portion are screwed with and fixed to each other. That is, the male thread portion 72b is screwed with the female thread portion 71b (refer to FIG. 6).

(28) In addition, the packing portion 60 is disposed between the piston accommodating upper portion 71 and the piston accommodating lower portion 72, and is fixed such that the packing portion 60 is sandwiched between the piston accommodating upper portion 71 and the piston accommodating lower portion 72. The packing portion 60 has an annular shape, and has a hole-shaped annular inner portion 61. The piston portion 50 is disposed to be slidable in the annular inner portion 61. It is preferable to make the packing portion 60 of rubber or a synthetic resin which has flexibility. In addition, the packing portion 60 is configured to secure watertightness between the piston portion 50 and the packing portion such that the air X containing components of a sucked liquid is unlikely to infiltrate into the case portion 40. For this reason, for example, the infiltration of the air X can be further blocked by applying grease to the piston portion 50 and the annular inner portion 61 of the packing portion 60. In a case of long-term use, the invention is not limited thereto as described above.

(29) The piston accommodating portion 70 has a hollow tubular pipette tip holding portion 71c which is long in the front end portion direction F, and the pipette tip 80 can be connected to the pipette tip holding portion 71c. The pipette tip holding portion 71c has a tapered shape that is gradually narrowed toward a tip portion direction F in plan view, and a filter 73 is fitted into a tip portion 76. In addition, the pipette tip holding portion has a slip stopper 74 made of rubber on an outer periphery of the tip portion 76, and the slip stopper makes connection to the pipette tip 80 reliable.

(30) The pipette tip 80 has a shape in which a tip portion 81 is thin and pointed, and is configured to easily suck a small amount of a liquid. In addition, the pipette tip has a tapered shape that gradually becomes thicker toward the rear end direction R when seen from the side, and has a hollow tubular shape. A rear end portion 82 is open, and the slip stopper 74 disposed on the outer periphery of the tip portion 76 of the pipette tip holding portion 71c is fitted to the rear end portion as described above. It is preferable to make the pipette tip 80 removable and of a transparent synthetic resin, and accordingly, the pipette tip can be replaced for each chemical solution to be used (refer to FIG. 6).

(31) The pipette device 10 having such a configuration can adjust an amount of a liquid to be sucked. Herein, in a case where the knob portion 22 of the pressing portion 20 is positioned on the rightmost side in the drawings, that is, in the rear end portion direction R, a position of the piston portion 50 from a bottom portion 75 of the piston accommodating portion 70 is set as an original position t (refer to FIG. 7).

(32) When a user presses the pressing portion 20 in this state, the piston portion 50 approaches the bottom portion 75 of the piston accommodating portion 70. This position is referred to as a first approach position t1 (refer to FIG. 2). The movement amount of the piston portion 50 in the piston accommodating portion 70, which is from the original position t (refer to FIG. 7) to the first approach position t1, is the amount of a liquid to be sucked. Herein, although the first approach position t1 does not change except for a case to be described later even in a case where an amount to be sucked is adjusted, the original position t of the piston portion 50 from the bottom portion 75 of the piston accommodating portion 70 in a case of a state where the pressing portion 20 is not pressed changes to approach the bottom portion 75. At the original position t which corresponds to a case where the pressing portion 20 is positioned to the farthest extent in the rear end portion direction R, a value of the graduation portion 43 is 6,000 (refer to FIGS. 2 and 4c). The graduation portion indicates 6,000 microliters at the maximum. It is preferable that a range of use in the embodiment be a range of 1,000 to 5,000 microliters. In addition, although it is preferable that the value of the graduation portion 43 be a capacity in a range of 0.2 to 2 microliters, a range of 1 to 10 microliters, a range of 2 to 20 microliters, a range of 10 to 100 microliters, a range of 20 to 200 microliters, a range of 200 to 1,000 microliters, or a range of 2,000 to 10,000 microliters, it is evident that the value is not limited to the capacities, depending on market requirements and a type of a chemical solution to be used.

(33) As described above, when the knob portion 23 or the second knob portion 27 rotates, the tubular portion 26 rotates. Since the female thread portion 41a is formed inside the first case portion 41 of the case portion 40 to be described later and the male thread portion 26a is formed also in the tubular portion 26, the tubular portion 26 is screwed with the case portion. When the shaft portion 21 is rotated about the axis, also the tubular portion 26 rotates, and the tubular portion 26 moves in the tip portion direction F of the shaft portion 21 with respect to the shaft portion 21. Accordingly, by moving the thick shaft upper end portion 32 of the piston rod portion 30 in the tip portion direction F, the piston portion 50 is also pressed and moves in the tip portion direction F. At this time, a graduation gradually decreases from 6,000 to 0.

(34) At this time, since the second spring portion 33b has a spring constant higher than the first spring portion 33a as described above, the first spring portion 33a is gradually compressed first. Simultaneously, the piston portion 50 also moves to approach the bottom portion 75 of the piston accommodating portion 70.

(35) When the knob portion 23 or the second knob portion 27 rotates, the first spring portion 33a is gradually compressed. When the piston portion moves to approach the bottom portion 75 of the piston accommodating portion 70, the thick shaft portion 32a passes through the center hole portion 33cc of the first washer portion 33c and comes into contact with the second washer portion 33d while the thick shaft upper end portion 32 compresses the first spring portion 33a. This position is a point where a graduation is “0”, and is a position where an adjusted position ts of the piston portion 50 (refer to FIG. 8) becomes the same position as the first approach position t1 (refer to FIG. 1).

(36) To describe in further detail, a suction amount is defined by the compression of the extended first spring portion 33a. Therefore, a position where the first spring portion 33a is compressed at the maximum, that is, a position where the thick shaft portion 32a passes through the center hole portion 33cc of the first washer portion 33c and comes into contact with the second washer portion 33d is a position to become the adjusted position ts of the piston portion 50. Also the adjusted position ts of the piston portion 50 is the same position as the first approach position t1 where the piston portion approaches the bottom portion 75 of the piston accommodating portion 70. Therefore, when the graduation becomes 0, the adjusted position ts separated away from the bottom portion 75 of the piston accommodating portion 70 in a state where the pressing portion 20 is not pressed becomes the point where the graduation is “0” (refer to FIGS. 4a and 8), and the adjusted position ts of the piston portion 50 becomes the same position as the first approach position t1 as described above. Thus, an amount of a liquid that can be sucked by the pipette device 10 becomes 0 since the first spring portion 33a cannot be compressed any further.

(37) In addition, when the knob portion 23 or the second knob portion 27 rotates reversely, the piston portion 50 moves in the rear end portion direction R. Accordingly, the position of the piston portion 50 changes to a position separated away from the bottom portion 75 of the piston accommodating portion 70.

(38) Therefore, when the piston portion 50 is at a position where a distance from the bottom portion 75 of the piston accommodating portion 70 is short, this position is the position of the piston portion 50 in a case of a state where the pressing portion 20 is not pressed. Thus, the movement amount of the piston portion 50 from the piston portion 50 in a case of a state where the pressing portion 20 is pressed to a position to the bottom portion 75 of the piston accommodating portion 70, that is, to the first approach position t1 becomes an amount of a liquid to be sucked by the pipette device 10. Consequently, when a distance between the piston portion 50 and the bottom portion 75 of the piston accommodating portion 70 is short, an amount to be sucked is small. When a distance between the piston portion 50 and the bottom portion 75 of the piston accommodating portion 70 is long, an amount to be sucked is large. The movement amount is made clear by the lower stage 43a, the middle stage 43b, and the upper stage 43c which are included in the graduation portion 43 displaying a three-digit number. The piston portion 50 can be disposed at any position between the original position t and the adjusted position ts, and this range can be freely adjusted. In addition, an accurate suction amount can be measured by the graduation portion 43.

(39) In a case of performing work of the pipette device 10 sucking a liquid, a user presses the pressing portion 20, and then the piston portion 50 is moved from a position to the bottom portion 75 of the piston accommodating portion 70, that is, any original position t to the first approach position t1 after adjusting a suction amount as described above. After then, the user takes the hand off the pressing portion 20, and a liquid chemical is sucked as the pressing portion 20 is restored in the rear end portion direction R by the elastic portion 33. The piston portion 50, the packing portion 60, the piston accommodating portion 70, the pipette tip holding portion 71c, and the pipette tip 80 are made of a synthetic resin, and thus there is no possibility of corrosion thereof in a case where this acidic or alkaline liquid is sucked. However, since the pressing portion 20 or the piston rod portion 30 is configured of stainless steel, there is a possibility of corrosion under certain conditions. While watertightness between the piston portion 50 and the packing portion 60 is maintained in a short period of time, the air X having a possibility of corrosion gradually leaks from a gap between the piston portion 50 and the packing portion 60 in long-term use, and infiltrates into the piston accommodating upper portion 71 of the piston accommodating portion 70 or the case portion 40 in some cases.

(40) Thus, by discharging the infiltrated acidic or alkaline air X from the air hole 49, corrosion of the piston accommodating upper portion or the case portion can be prevented. This can be performed by the following operation. That is, when a user presses the pressing portion 20 of the pipette device 10, the piston portion 50 moves toward the bottom portion 75 of the piston accommodating portion 70 through the piston rod portion 30 (refer to FIG. 2), and moves to the first approach position t1 where the piston portion approaches the bottom portion 75 as described above. In this state, a liquid (not illustrated) infiltrates into a pipette tip 80, and the user takes the hand off the pressing portion 20. Accordingly, the elastic portion 33 returns the pressing portion 20 in the rear end portion direction R. Consequently, when the piston portion 50 moves in a direction of separating away from the bottom portion 75 of the piston accommodating portion 70, that is, the rear end portion direction R, the liquid is simultaneously sucked from the pipette tip 80 (refer to FIG. 7). When the user presses the pressing portion 20 of the pipette device 10 again, the piston portion 50 moves toward the bottom portion 75 of the piston accommodating portion 70 through the piston rod portion 30, and the piston portion 50 is disposed at the first approach position t1 where the piston portion approaches the bottom portion 75. Thus, the sucked liquid can be discharged. The sucked liquid cannot be completely discharged in some cases depending on the viscosity of the liquid. At this time, the user further presses the pressing portion 20 of the pipette device 10. Accordingly, the second washer portion 33d is further pressed from the position where the first spring portion 33a is compressed at the maximum, that is, the position where the thick shaft portion 32a passes through the center hole portion 33cc of the first washer portion 33c and comes into contact with the second washer portion 33d. Accordingly, the second spring portion 33b having a spring constant higher than the first spring portion 33a is further compressed, and the piston portion 50 comes into contact with the bottom portion 75 of the piston accommodating portion 70. Accordingly, the sucked liquid can be completely discharged from the piston accommodating portion 70 (not illustrated), and the pipette device 10 can suck and discharge an accurate amount of the liquid.

(41) However, in some cases, the air X containing components of the liquid enters the case portion 40 via the piston accommodating upper portion 71 of the piston accommodating portion 70 from between the piston portion 50 and the packing portion 60 in long-term use. Accordingly, metal parts disposed in the piston accommodating portion 70 and the case portion 40 have a possibility of corrosion.

(42) In order to prevent the corrosion, the case portion 40 has the air hole 49. That is, as the piston portion 50 moves from the first approach position t1 in the rear end portion direction R, the air X staying in a case 40 is discharged from the air hole 49 (refer to FIG. 7).

(43) As the piston portion 50 is again pressed in the tip portion direction F after then, this time, external air is newly introduced into the case portion 40 or the piston accommodating portion 70 from the air hole 49 (refer to FIG. 2). The air X is discharged from the air hole 49, or fresh air is introduced in response to motion of the piston portion 50 moving in the front end portion direction F and the rear end portion direction R as described above. Therefore, although the piston rod portion 30 disposed inside the piston accommodating portion 70 and the case portion 40, the long shaft portion 21 of the pressing portion 20, and the first spring portion 33a, the second washer portion 33d, and the second spring portion 33b of the elastic portion 33 can be configured of a metal, a possibility that the metal parts are exposed to the acidic or alkaline air X generated from the sucked liquid for a long period of time is low. Although the air X is discharged from the air hole 49 in response to motion of the piston portion 50 moving in the front end portion direction F and the rear end portion direction R, the air X is not necessarily prevented from flowing out from the air hole 49 even in a case where the piston portion 50 is stopped.

(44) In addition, such operation is repeated each time the piston portion 50 moves. Therefore, the corrosion of the metal parts can be prevented in normal use of the pipette device 10. Since corrosion can be prevented by newly providing the air hole 49 as described above, making a change in a material of a metal part or performing surface treatment such as plating is not necessary, and thus corrosion can be prevented without incurring additional costs.

(45) In another embodiment, it is preferable to dispose a second air hole 49a in the piston accommodating upper portion 71 of the piston accommodating portion 70 in another pipette device 10A (refer to FIGS. 9 and 10). Specifically, since the air X containing components of a liquid enters the piston accommodating upper portion 71 from between the piston portion 50 and the packing portion 60, the corrosion of metal parts disposed in the piston accommodating portion 70 and the case portion 40 can be prevented by providing the second air hole 49a in the piston accommodating upper portion 71. A method of discharging the air X, in this case, is the same as described above. Therefore, although the air X is discharged from the air hole 49a in response to motion of the piston portion 50 moving in the front end portion direction F and the rear end portion direction R, the air X is not necessarily prevented from flowing out from the air hole 49a even in a case where the piston portion 50 is stopped.

(46) It is preferable to provide the air hole closer in the rear end portion direction R than the piston accommodating upper portion 71 of the piston accommodating portion 70 is. Another pipette device 10A has the same configurations as the pipette device 10 of the first embodiment except for the position of the air hole 49a. It is preferable to dispose the air hole to be positioned closer in the rear end portion direction R than the position of the packing portion 60 is. In such a manner, it is also possible to additionally dispose the second air hole 49a while disposing the air hole 49. Therefore, a plurality of air holes 49 and a plurality of second air holes 49a can also be disposed although not illustrated. In addition, the plurality of air hole 49 or the plurality of second air hole 49a can also be disposed.