EP0181957A1 - Adjustable-volume pipette - Google Patents

Abstract

The pipette, which contains a pushbutton-operated metering piston block, an adjustment screw block connected to the latter and progressively limiting the travel of the piston block, a mechanical decimal counter to indicate the set volume, and a discharge block and a terminal ejection block, is characterised in that its metering block is of divisible construction in order to cover the entire metering range assumed for micropipettes. The division is achieved by mounting the adjustment block in the handle (1). The discharge block, which contains the small magnetic plate (25), is also situated in the handle (1) beneath the counter (16). The second part of the metering block is formed by replaceable metering stems which are screwed into the handle (1). The metering stems contain roller-shaped plungers (33) having various diameters. <IMAGE>

Description

The invention relates to a handheld pipette for the exact repeatable dosing of small and very small liquid volumes with the possibility of changing the volumes of the measured doses in a fluid manner.

It is generally assumed that the manually operated mechanical dosing devices, depending on the size of the measured doses, in macropipettes with a volume of 1 ml upwards, up to a maximum of 20 - 30 ml and in micropipettes with a volume of 1 ml downwards up to the order of 2 or even divide by 1 microliter. Depending on their design, the mechanical pipettes are used in dosing devices with an unchangeable volume, dosing devices with abruptly selected, unchangeable volumes and dosing devices with the volume that changes in a certain range.

The present invention relates to the group of micropipettes with the volume which changes fluently in a certain range.

The group of micropipettes, irrespective of whether their volume is constant or variable, is also characterized by certain, generally accepted working cycles which follow the suction of the measured amount of liquid into the end piece. The first cycle consists in emptying the aspirated dose from the end piece, the second in the so-called blowing out i.e. Ventilate to remove any residue of the measured amount of liquid and finally the third cycle in the discharge of the one-time, replaceable end piece used for dosing. It was assumed that the cycles mentioned take place in this order in one go under the pressure of the thumb, the beginning of the second and third cycles being signaled by the emergence of an abrupt force threshold, after the overcoming of which only the execution of the given one Cycle occurs. The working cycles, as well as the changes in the dosing volume and the dose size form the generally recognized determinants in the development of micropipette designs.

From United States Patent No. 4,096,751 is a hand-operated micropipette with a certain degree fluid volume known. This pipette has a body with a droplet cross-section, which forms the handle, and a cylinder, which represents the extension of this body and gradually tapers, with a sleeve of the end piece ejector placed on it. A long piston rod, also with a long rod plunger inserted in the cylinder and peripherally sealed from the upper part of the mechanism, is fitted inside the body. The piston rod consists of several interconnected functional segments. The upper part of the piston rod protruding beyond the body has the shape of the cross-sectional field similar to the letter D and is completed with an ergonomic push button. On the flat surface of the letter D there is a linear single scale, referring to the upper edge of the body. Below the scale section, the piston rod has a screw-shaped section on which there is a screw nut with an external oblong multi-groove profile. This screw nut is inserted inside a rotatable sleeve, which has a toothed wheel on the outside, which with someone else. has the function of an adjusting knob and is coupled with a decimal gear wheel. The inside of the sleeve has a multi-groove profile corresponding to the multi-groove profile on the screw nut of the piston rod over a certain length and is closed from below by a plate under which a spiral pressure spring is located. Below the screw part, the piston rod has a cylindrical shape, a stop flange being formed on the piston rod directly below the screw nut. Spiral return springs of the dosing and blow-out mechanism are inserted below the plate.

The end piece ejection mechanism is located parallel to the piston rod axis, but in a separate seat shaped in the handle. This mechanism consists of a rod plunger with a return spring supported on the seat base. The push button is attached to the upper end of the plunger with a rugged upper edge. The lower end of the plunger penetrates the hole in the seat base and is screwed to the flange-shaped board of the ejector sleeve, which is slidably mounted on the cylinder.

The volume range of the described micropipette is determined by the maximum length of the plunger stroke. This length is determined by the distance that the stop flange has to travel from the upper locking position to the surface of the plate forming the movable sleeve base. The stroke length is changed by turning the scaled toothed wheel, which causes the rotary movement of the sleeve and the screw nut coupled to it through the multi-groove profile, which is screwed onto the piston rod part with a cut thread. Since the upper face of the nut rests on the outer board in the sleeve, its rotation calls for screwing the piston rod into the nut and lowering or raising the position of the stop flange, or in other words, shortening or extending the path of the latter Flange for collision with the surface of the plate-like sleeve bottom. Generalizing, it can be said that the change in the stroke length of the plunger takes place by a variable limitation of its upper position while maintaining the unchangeable lower position. The screw stroke on the The piston rod and the translation of the toothed transmission transmitting the movement from the adjusting knob to the sleeve, as well as the plunger diameter, are selected such that one revolution of the toothed adjusting knob causes the piston rod to be displaced by a scale part or by a full unit and the scale part on the adjusting knob is a fraction of this unit corresponds.

After setting the selected can volume and attaching the end piece, the push button on the piston rod is pressed and the piston rod is inserted into the body. This movement causes the plunger in the cylinder to move to the depth measured by the actual height of the flange stop above the bottom of the sleeve. After the resistance, which indicates that this distance has been reached, the end piece is immersed in the liquid and the pressure on the push button is released evenly with a controlled movement. Under the action of return springs, the system, and with it the plunger, returns upwards, causing the liquid to be sucked into the end piece. This takes until the mechanism picks up the top layer Has reached rest position, which is synonymous with the removal of the measured dose.

The pipette is emptied by pressing the push button again, which in the first phase causes the plunger to be moved down by the set stroke and the liquid to be ejected from the end piece. When the flange stop hits the plate surface, the further pushing in of the piston rod encounters an increased resistance caused by the additional effect of the spring supporting the plate. Overcoming the resistance of this spring causes the plate to tear off the sleeve face and permits an additional stroke of the plunger. This additional stroke represents the discharge stroke of the remains of the liquid from the end piece and is always of a constant height, since the foot of the piston rod push button pushes against the upper surface of the body, which makes further movement of the piston rod impossible. Now the drop cycle can take place. To do this, the thumb is removed from the piston rod pushbutton and the pressure is transferred to the adjacent pushbutton on the ejector. Its impressions causes the movement of the plunger downwards, which acts on the flange of the ejector sleeve and pulls it down from the plunger cylinder, the sleeve with its edge throwing off the end piece from the nozzle-shaped cylinder outlet.

Another solution of the micropipette with a fluidly changing volume is known from the patent specification of the United States of America No. 4,250,755. In the body forming the handle, a long sleeve is pressed with a thread cut inside, in which there is a plunger plug with a thread cut outside and a hexagonal through hole. This hole is penetrated by the hexagonal piston rod, which is closed with a round push button. A mechanical decimal counter mounted on the hexagonal piston rod is attached to the upper part of the body. Below the stopper plug, the piston rod assumes a cylindrical shape in order to merge into a long rod plunger further down. Under the stopper is on the cylindrical part of the piston rod by the force of the return spring used on the piston rod below the stop ring on the forehead of the Stopper-pressed, annular stop attached. The length of the plunger stroke in this solution is determined by the height of the lower button surface above the upper body surface. The stroke length is changed by the rotation of the piston rod, which causes the rotation of the stopper plug and a less or more deep insertion of the piston rod into the interior of the sleeve defined in the body and, as a result, a lower or higher position of the push button above the pipette body. The rotation of the piston rod simultaneously causes the rotation of the last plate of the digital counter, the number of which is visible in the window, which is cut out in the body. The number size of the counter expresses the size of the set dose in microliters. The dose is measured by pressing the pushbutton until its lower surface is supported on the upper surface of the body. The described micropipette forms a single cycle device, the construction of which does not provide for the discharge and the endpiece ejection cycle to be carried out.

One of the above-mentioned micropipette kinematically similar pipetting device, but with the volume reading on the linear scale, which is plotted on the side surface of the body, is described in French Patent No. 2,427,133.

In the known pipettes described above, there is a common, essential design feature, namely a composite construction of the metering block with the plunger stroke calibration block, the reading block, the setting block and even the blow-out block. This causes kinematically disadvantageous working conditions of these blocks, especially the calibration and dosing blocks. As the components of the plunger stroke calibration block move during removal and emptying of the pipette end piece, they become susceptible to mechanical wear, which can influence the gradual decalibration of the pipette. Rotational movements of the components, the mutual position of which limits the working stroke of the dosing mechanism, result in the introduction of systematic, cyclically variable setting errors which result from the forehead of the resistance surfaces of these components. In addition, the known pipettes were autonomous devices built with a certain dosing range, within which a fluid volume change is possible. So in order to cover the full range assumed for micropipettes, that is from 1 to 1000 microliters, the user must provide himself with a set of special devices with complementary areas for the full range.

The object of the invention is to develop such a pipette construction, the metering block of which would be kinetically independent of the other blocks of the mechanism and that an adjusting block could encompass the entire metering range assumed for micropipettes.

This was achieved according to the invention in such a way that the plunger metering block can be divided and the division is carried out in such a way that the adjustment block is built into the pipette handle, which consists of a plunger rod pulled through the calibration tube, which is closed with a push button and ends in a stop block , from the forehead a free, thin connector is led out, at the end of which a magnetic coupling is firmly clamped. The calibration screw is in the nut-like bottom with the Push-button coupled and with the forehead in the seat of the immovable body of the digital drum counter, screwed, rotatable switching sleeve, whereby in the handle below the counter there is the blow-out block, which contains a magnetic plate, which is displaceable in the seat flange, due to the section-wise reduction of the inside diameter of the handle, received guidance, arranged spacer sleeve is attached. The second part of the dosing block consists of interchangeable dosing shafts that are screwed into the handle. The dosing shafts contain roller-shaped plungers with different diameters, which are closed off by plate-shaped anchors made of ferromagnetic material and central locking bolts projecting beyond these anchors made of non-magnetic material. Each of these metering shafts consists of a cylinder with a flange, in which a thread is cut on the outside which corresponds to the thread in the handle, a tube provided with a nozzle being pressed into the bottom of this cylinder, which tube is pushed along the entire length by a a filler with a channel is taped and onto this tube an ejector sleeve coupled to a pin plunger with a ring which is inserted within a cup-shaped sleeve arranged above the cylinder is slidably pushed on. Furthermore, according to the invention, reducing sleeves, the inner diameters of which are adapted to the plungers for the given volume range, are tightly inserted in the cylinders in the metering shafts equipped with plungers with smaller diameters than the plunger for the area of maximum volume. In the handle, between the inner wall and the foreheads of the counter drums, a sliding cover frame is attached, the arm of which rests on the outer flange of the cup-shaped sleeve. When the cover frame is in flight, a symbol is arbitrarily formed which symbolizes the limit of the decimal fraction. In connection with this, the outer flange of the cup-shaped sleeve has a different height in each of the exchangeable metering shafts. The switching sleeve is connected to the mechanism of the drum counter by means of the separably inserted connecting sleeve, however after the setting position has been compensated for with the counter zero blocked in the screw-shaped bottom of the sleeve. The gearshift sleeve also has an inner, in an outer wall of the push-button type oblong groove inserted wing-like board. The forehead of the gearshift sleeve is rotatably inserted in the seat formed in the upper part of the drum counter body, on the other hand the bottom of this seat is designed as a horizontal toothed disk which cooperates with the index attached in the gearshift sleeve from the forehead. The entrance to the channel in the dosing shaft is made in the side wall of the conical outlet of the filler.

The solution according to the invention is characterized by an advantageous kinetic arrangement, since the piston metering system is a completely independent system which is not burdened by the transmission of any additional forces. The remaining function blocks are installed concentrically around the dosing system, so that the force that actuates them does not act on this system. The separation of the block calibrating the plunger stroke from the reading block allows these two blocks to be easily assembled and their zeros to be precisely synchronized. This increases the accuracy of setting and dimensioning the cans. In addition to the technical advantages, there is also the advantage of Pipette according to the invention in the possibility of using a single calibration block for the volume range full for micropipettes, which is adapted for this purpose by the simple exchange of metering shafts.

The invention is explained on the basis of exemplary embodiments which are shown in the drawing, in which FIG. 1 shows the pipette in longitudinal section and FIGS. 2 and 3 also in longitudinal section two exemplary designs of interchangeable metering stems for two different areas of the can volumes.

The pipette according to the invention basically consists of the handle, in the interior of which the following components are permanently installed: block for setting the metering volume, block for reading the set volume and the blow-out block, as well as the metering stems connected to the handle and adjustable to different areas. The dosing shaft set specified in the exemplary embodiment is based on three volume ranges: 2-10 microliters, 10-100 microliters and 100-1000 microliters with the possibility of choosing any volume in each of the specified ranges.

The adjusting block used in the handle 1 contains an axially attached piston rod 2, which runs out into a hollow pressure cup 3 protruding beyond the handle 1. The lower end of the piston rod 2 is terminated with the stop block 4, the initial roller shape of which has been somewhat sheared off along the side by a parallel to form guide surface extending to the axis. A thin, free rod connection piece 5, terminated with a magnetic coupling 6 in the form of a sleeve permanent magnet, is derived from the forehead of the stop stone 4. On the piston rod 2, the calibration screw 7 with a precisely executed thread is slidably inserted, which piston rod is sheared outside for a certain length, this shearing being in one plane with the shearing on the stop stone 4. The calibration screw 1 is screwed into the nut-forming bottom of the selector sleeve 8 rotatably inserted in the handle 1, but through a plate-shaped contact piece 9 with a spring. The inner diameter of the switching sleeve 8 is larger than the diameter of the push button 2, which freely axially into the interior of the sleeve 8 can be introduced. The sleeve 8 also has an inner, oblong, wing-shaped board, which is inserted into an oblong groove 11 made in the outer wall of the pushbutton 3 over its entire length. A spiral return spring 12 is inserted between the bottom of the push button 3 and the bottom of the seat in the calibration screw 3 on the piston rod 2. The setting block is supplemented by the vacuum return damping system arranged inside the hollow pushbutton 3. This system is in the form of a cylinder 13 designed through the interior of the pushbutton 3 and has an elastic piston 14 which is fixed immovably on the upper end of the calibration screw 7 relative to the cylinder 13. In the wall of the pushbutton 3 there is one from the edge certain depth a small recess 15 for the appropriate ventilation of the cylinder 13 in the final phase of its movement.

The reading block of the set volume is located below the setting block in the handle 1, the main component of which consists of a decimal drum counter 16 arranged near the wall of the handle 1 in the light of the window 17 arranged in the wall. The The counter 16 is installed in the body 18 immovably inserted within the handle 1 on a flat ferromagnetic plate 19. The body 18 with a complicated shape has several functions. In the upper part of the body 18 there is a seat, on the bottom of which the switching sleeve 8 is pressed frontally. The bottom of the seat is in the form of a horizontal toothed disk, which cooperates with the index 20 attached from the forehead to the indexing sleeve 8, thereby ensuring that the mechanism of the adjusting block is clearly synchronized with the counter 16. Within the body 18 there is an axial flow bore 21 with a flattened wall, which bore has the function of guiding the stop stone 4 and the calibration screw 1, which does not permit any movement of these components. Below the seat, on the cylindrical board formed in the body 18 around the bore 21, an intermediate gear 22 driving the drum counter 16 is rotatably mounted. The transfer of the rotary movement of the switching sleeve 8 to the counter 16 takes place with the aid of the connecting sleeve 23, which is used separately, but in a corresponding one Position blocked in the screw-shaped bottom of the shift sleeve 8 and the intermediate gear 22 is coupled to the counter 16. The reading block is also equipped with a sliding cover frame 24, which is attached between the inner wall of the handle 1 and the foreheads of the drums of the counter 16 in the light of the window 17. On the cover frame 24 from the side of the window 17 there is a sign in the form of, for example, a vertical line, comma or dot, which arbitrarily symbolizes the limit of the decimal fraction.

The blow-out block is attached in handle 1 below the reading block and concentrically with the plunger of the metering shaft. This block has a flat magnetic plate 25 with a hole through which a free, thin connecting piece 5 passes loosely. The magnetic plate 25 on a ferromagnetic washer is pressed into the front nest in the spacer sleeve 26. The axial guidance of the spacer sleeve 26 was achieved by reducing the inside diameter of the handle 1 in sections. The spiral return spring 27 of the blow-out block is located between the peripheral threshold formed in this way and the flange of the sleeve 26.

The interchangeable metering shafts are shown in the exemplary embodiments in FIGS. 2 and 3. Each shaft consists of a cylinder 28 with an externally threaded flange, the diameter of which corresponds to the internal thread in the outlet of the handle 1. A tube 21 is pressed into the bottom of the cylinder 28 and ends in a nozzle 30 placed thereon. In order to reduce the so-called dead volume, a filler 31 with a conical outlet is tightly inserted into the tube 29 along its entire length. The filler 31 has a channel 32 along its entire length, the entrance of which is made in the side wall of the conical outlet of the filler 31. A typical, interchangeable end piece, which was not shown in the drawing, is placed on the end of the connection piece 30.

The plunger 33, which is sealed with a circumferential seal 34, cooperates with the cylinder 28. The plunger 33 has the shape of a roller and is closed with a plate-shaped armature 35 made of ferromagnetic material and a central locking bolt 36 projecting beyond this armature made of non-magnetic material. The principle of the unchangeable maximum stroke of the dosing block was adopted in the pipette according to the invention, which is revealed in the maintenance of a calibration screw and a cylinder diameter. However, in order to ensure the possibility of changing the can volume in the entire area for micropipettes, the maximum volume of the metering block for the given sub-area must be changed accordingly. In order to achieve this goal, the diameters of the plungers 33 are changed in individual dosing shafts, and by maintaining the constant maximum inner diameter of the cylinder 28, a reduction sleeve 37 with an inner diameter corresponding to the diameter of the plunger 33 for the given sub-range of the dosing volume is pressed into the same .

The dosing shaft is also equipped with an end piece ejection block. This block consists of a cup-shaped sleeve 38 arranged above the cylinder 28, within which a ring 39 is movably inserted, via the pin plunger 40, onto the ejector sleeve 41, which comprises the cylinder 28 and is guided on the tube 29. A spiral return spring 42 of the ejector is attached within the ejector sleeve 41 in the area of the tube 29. The Pot-shaped sleeve 38 has an outer flange 12 which controls the displacement of the cover frame 24 which sets the decimal sign between the individual drums thereof in the field of view of the counter 16. Since the dosing shafts mentioned change the ranges of the dosing volume in the decimal interval, the height h of the flange is variable and adapted in such a way that when the dosing shaft is replaced by a shaft with a different volume range, the cover frame 24 is automatically shifted according to the actual need to set the decimal point . For example, if a dosing shaft labeled with a maximum volume of 10 microliters is inserted, then the set cover frame 24 will give the reading image of 10.00 and if it will be a dosing shaft with a maximum volume of 100 microliters, the image will accordingly have 100.0. With a maximum volume of 1000 microliters, the decimal point, as unnecessary, is moved outside the field of view.

The functioning of the pipette according to the invention is described below with reference to FIG. 1 of the drawing. After the selection of the required range of the dosing volume is in the Handle 1 of the corresponding dosing shaft screwed in for this area. During this activity, the non-magnetic locking pin 36 goes centrally into the bore of the magnetic coupling 6 and brings the ferromagnetic plate armature 35 into exact contact with the face of the magnet of the coupling 6. The metering block is then connected to the volume setting block by the force of the magnetic field of the coupling 6. Simultaneously, which support on the Aussenfl _a nsch 43 of the cup-shaped sleeve 38, the cover frame arm 24 in respect to the drums of the counter 16 appropriate position for the designation of the Dezimalbruchzeichens for the selected measurement range of the cover frame 24th

The desired can volume is set by turning the pushbutton 3, which transfers the rotary movement to the switching sleeve 8 by means of the coupling of the groove 11 with the wing-shaped board 10. The rotation of the sleeve 8 causes it to be screwed into the screw-shaped bottom of the calibration screw 7, on the end of which the stop block 4 is pressed. Since the stroke length of the plunger 33 by the length of the path that the stop stone 4 from the upper locking position to the upper surface of the magnetic plate 25, arbitrarily referred to in the drawing with the word "DOZA" / DOSE /, is to be determined, the change in the height at which the forehead of the calibration screw 7 is located also calls for a change in the height of the locking position of the the return screw 12 on the forehead of the calibration screw 1 pressed out stop stone 4. The rotational movement of the switching sleeve 8 is simultaneously transferred through the connecting sleeve 23 rotated together with the sleeve 8 to the intermediate gear 22 and further to the drum counter 16, which numerically represents the height of the face of the calibration screw 7 each time in volume units. After setting the required volume and placing it on the nozzle 30 of the end piece suitable for the given area, the pipette is prepared for the withdrawal of the dose. Then the push button 3 is pressed until the first sensible resistance, which causes the movement of the piston rod 2 down and the displacement of the stop stone 4 until its forehead rests on the surface of the magnetic plate 25. This movement is transferred via the free connector 5 to the plunger 33, which in the cylinder 28 in one of the ways covered by the stop stone 4 and designated by the word "DOZA" / DOSE / analog depth is inserted. The downward movement of the pushbutton 3 also causes the elastic piston 14 to be introduced into the interior of the cylinder 13. The end piece is then immersed in the liquid to be removed and the pressure on the pushbutton is completely released. Under the action of the return spring 12, the mechanism returns to the top position.

The return causes the creation of negative pressure in the cylinder 13, which slows down the return of the pushbutton 3, makes this return relatively uniform and thus enables an exact suction into the end piece of the amount of liquid measured by the stroke of the plunger 33. At the end of the return, when the recess 15 comes to the edge of the piston 14, the interior of the cylinder 13 is ventilated and the return spring 12, which is no longer held back by anything, surely strikes the stop stone 4 against the face of the calibration screw 7.

The dose is removed from the end piece when the push button 3 is pressed again until the first sensible resistance, that is, until the moment the stop stone 4 is supported on the surface of the magnetic plate 25. That is the duty cycle. A further push of the push button 3 introduces the blowdown cycle, which can be felt by the formation of the sudden force threshold, since the force of the return spring 12 is now the force of the blowout spring 27 and the force of the magnetic field of the ferromagnetic plate 19 on which the body 18 of the Counter 16 rests, adhering magnetic plate 25 is added. Overcoming this sum of forces causes the magnetic plate 25 to be torn off the plate 19 and its movement together with the spacer sleeve downwards until the end of the sleeve 26 abuts the end of the ring 39. This movement, designated in the drawing with the word "WYDMUCH" / EXHAUST / arbitrary, also causes the plunger to be moved by an additional stroke and the end pieces to be ventilated.

Then the discharge cycle of the empty end piece begins and the path of this movement is arbitrarily designated in the drawing with the word "ZRZUT" / ABWURF /. If the push button 3 is pressed in even further, then the spacer sleeve 26 presses with its forehead onto the ring 39 which, after overcoming additional resistance of the return spring 42 of the ejector, presses with the plungers 40 onto the wing-like members of the ejector sleeve 41.

The axial movement of the ejection sleeve 41 brings about the collision of its forehead with the forehead of the end piece attached to the connection piece 30 and strips this end piece off the connection piece 30. Now the pressure on the push button 3 is released and under the action of return springs, the pipette mechanism returns with a movement controlled by the damping block until it reaches the rest position, after which it is ready for the following working cycle.

Claims (10)

1. Pipette with variable dosing volume, which forms a hand-operated device which has a dosing piston block driven by a pushbutton, an adjusting screw block connected to this block, which fluidly delimits the stroke length of the piston block, and a mechanical decimal counter indicating the size of the set volume. as well as a blow-out and an end piece ejection block, characterized in that to cover the entire metering range assumed for micropipettes, their piston-metering block is divisible and the division is carried out in such a way that the adjustment block is built into the handle / 1 / consists of a piston rod / 2 / pulled through the calibration screw / 7 /, which is completed with the pushbutton / 3 / and ends in the stop block / 4 /, from the front of which the free, thin connecting piece / 5 / is axially guided, on the end of which The magnetic coupling / 6 / is firmly clamped and the Calibration screw / 7 / is screwed into the screw-nut-shaped bottom of the rotatable switching sleeve / 8 / which is coupled to the push button / 3 / and with its forehead in the seat of the immovable body / 18 / the digital drum counter / 16 /, but in the handle / 1 / is located below the counter / 16 / the blow-out block, which contains the magnetic plate / 25 /, which is mounted in the seat flange of the spacer sleeve / 26 /, which is displaceably arranged by reducing the inner diameter of the handle / 1 / guide: the second part of the dosing block form interchangeable dosing shafts, which are screwed into the handle / 1 / and roller-shaped plungers / 33 / with different diameters, which are formed by plate-shaped anchors / 35 / made of ferromagnetic material and protruding centric rasps / 36 / made of non-magnetic material are complete and each of these dosing shafts from a cylinder / 28 / with egg A flange, in which there is a thread cut in the outside, which corresponds to the inner thread in the handle / 1 /, in the bottom of this cylinder / 28 / a tube / 30 / provided with a socket / 29 / is pressed in, which is tapped over the entire length through the one channel / 32 / having filler / 31 / and on the tube / 29 / one via pin plunger / 40 / with the ring / 39 / which is inside the above the cylinder / 28 / arranged cup-shaped sleeve / 38 / is inserted, coupled ejector sleeve / 41 / is slidably pushed on. 2. Pipette according to claim 1, characterized in that in the metering shafts equipped with plungers / 33 / with smaller diameters than the plunger for the maximum volume range into the cylinders / 28 / reducing sleeves / 37 / with inner diameters which are connected to the plungers / 33 / are adjusted with the given volume range, are tightly pressed. 3. Pipette according to claim 1, characterized in that between the inner wall of the handle / 1 / and the drum heads of the counter / 16 / a sliding cover frame / 24 / is attached, the arm of which is on the outer flange / 43 / the cup-shaped sleeve / 38 / supports. 4. Pipette according to claim 3, characterized in that on the escape of the cover frame / 24 / a symbol which arbitrarily symbolizes the limit of the decimal fraction is executed. 5. Pipette according to claim 3, characterized in that the outer flange / 43 / the cup-shaped sleeve / 38 / in each of the interchangeable metering shafts has a different height / h /. 6. Pipette according to claim 1, characterized in that the switching sleeve / 8 / is connected by means of the separable, but in a corresponding position in the screw-shaped bottom of the sleeve / 8 / blocked connecting sleeve / 23 / with the mechanism of the drum counter / 16 /. 7. Pipette according to claim 1, characterized in that the switching sleeve / 8 / has an inner wing-like board / 10 / and that this board is inserted into an oblong groove / 11 / formed in the outer wall of the push button / 3 /. 8. Pipette according to claim 1, characterized in that the forehead of the switching sleeve / 8 / is rotatably inserted in the seat formed in the upper part of the body / 18 / the counter / 16 / and that the bottom of this seat as one with the the front of the gearshift sleeve / 8 / attached index / 20 / cooperating lock washer. 9. Pipette according to claim 1, characterized in that the entry into the channel / 32 / in the side wall of the conical outlet of the filler / 31 / is carried out. Pipette with variable dosing volume LIST OF REFERENCES 1 - handle 2 - piston rod 3 - push button 4 - stop stone 5 - connector 6 - magnetic coupling 7 - calibration screw 8 - Shift sleeve 9 - plate-shaped pressure piece 10 - wing-like board 11 - groove 12 - Return spring 13 - cylinder 14 - elastic piston 15 - recess 16 - drum counter 17 - window 18 - meter body 19 - ferromagnetic plates 20 - index 21 - flow hole 22 - intermediate gear 23 - connecting sleeve 24 - cover frame 25 - magnetic plates 26 - spacer sleeve 27 - Return spring 28 - cylinder 29 - tubes 30 - sockets 31 - fountain pen 32 - channel 33 - Plunger 34 - seal 35 - plate anchor 36 - locking pin 37 - Reduction sleeve 38 - cup-shaped sleeve 39 - ring 40 - pestle 41 - Ejector sleeve 42 - Return spring of the ejector 43 - outer flange

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