HU230504B1 - Multi-purpose unit for handling liquid components found in samples - Google Patents

Abstract

The invention relates to a multipurpose unit for the handling of samples containing liquid components, especially for preparing the analysis of blood sample. The multipurpose unit contains a sampling part unit (10), having a lower stationary member (11), an upper stationary member (13) and a moving member (12). The moving member (12) has a sample holder passage (12a), the upper stationary member (13) has upper sample transfer passage (13a) co-acting with the sample holder passage (12a) and/or the lower stationary member (11) has lower sample transfer passage (11a) co-acting with the sample holder passage (12a). The passage (13a) and/or passage (11a) is connected to a sampling piece (30). The upper stationary member (13) is paired with a reactor part-unit (14) containing preparation chambers (14a,14b) and has ducts (15a,15b) leading from the chambers (14a,14b) to the upper delimiting surface (12b). The moving member (12) has a measuring zone (20) with a measuring passage (16). The device can be operated with the use of a lower amount of reagents, more cost efficiently, with a lower number of parts and more reliably.

Description

Multipurpose unit for handling liquid components containing liquid components

FIELD OF THE INVENTION The present invention relates to a multipurpose unit for treating specimens containing a liquid component, in particular for preparing a blood sample evaluation comprising a subassembly with a lower up member and a lower moving member with an upwardly movable moving member. the moving member of the component is provided with a sample passage, while the upper stationary member is cooperated with the sample passage by at least one dali 'upper mmu dare: amr, J es saey a? lower "LIO member m.itai" has RTE '.cutms ee \ jltmn.rtU »' fe _c aLbb EGX piece dsobb mmnárte / ε-ιο ntrattal, the higher quality mg mrtu'A núntaatverrtc passage and / or the lower member consisting of and the lower miniature passageway is in contact with a sampler.

'Out <mho íortaöeKOxs and FEU ifel ski foi λ \ ο> _k ck \> AMI, x ¹ "oue t, be employed for, included are the hematologic vending machines, which is an essential part of the sampling unit, which is usually the sampling Tot , includes an element capable of extracting the sample with sufficient accuracy, and a unit for moving the blood sample to be measured to the desired location. Another essential part of hematological automata is the venom, which contains the measuring chamber for the diluted blood sample to be used for testing the diluted blood sample and the fluid moving element which transmits the blood sample to the measuring chamber. In general, the sampling unit and the measuring unit are independent of each other.

GB 2,459,122 discloses a sampling device in Krlejezebe, while sample measuring devices are known from epho-makers. See, inter alia, GB 1,064,813, WO 2004/003517 and WO 2013/002213.

One of the major drawbacks of these solutions is that the physical separation of the two main components includes a large number of pipe sections, connections and control valves for moving the fluid, resulting in large-scale, increased power and reagent requirements, and failure due to many controlled components. prone.

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US 2012/012213 $) arable release! from the document there is known a so-called "ntfofloidic" device which is suitable for the sample; however, it has the disadvantage that it is not suitable for collecting, producing and transmitting the test sample in sufficient quantities.

On this. The general drawback of known tools is that they perform two tasks in two separate structures rather than in separate structures. Further disadvantages are that volume n ttb'Od ke · '? M, e \ e-emt'e mu.u.g \ ^ egbum -a \ m tata. , e ex. m \ y, e, 'ende'l em.no, e> no a mernem eav.ags, mmmk s η-, kennels are compressed.

US '' -Ά SSS Lbtunn.í years old s abadabn! wash away> any other file that is .dk other than sample removal and testing. The point is that there are several similarly structured, 1 ijiw, -following “foefemw! uk <^ ve ^r m \ .m 1 ekkori t>.

the other, the selector valve, which is also a separate unit, and the third is the drain valve. Given. stand-alone units carry out stand-alone tasks in reactor baths. located in the reactor in the rain m'taeal, the memndo amagea, the reagent, and is poured makim esouAei A / 'some of the speeps are structured ohm. "Bypass valves" which, through the passageways in the intercalating limbs, are injected into the tubes in the central movable part, which draws off a quantity of fluid from the stream of streams and can deliver a precisely defined amount of medium, pb or to the desired location.

The disadvantages of the apparatus disclosed in this patent are that they are large in size and consist of a number of structural elements between which the sample and the reagents are transmitted by a network of effective lengths which, in use, pose a serious hazard to the material.

A further disadvantage is that due to the large number of parts, there is a high risk of failure and a high maintenance requirement, ^k e <í '\ v ⁽ 1 \ J mbe o v'ag m-rnmoek> ίο · κ - f, v'). , and the failure of a single component may result from the inoperability of a complete unit.

.a \>> '> \ \ O Mén? em v * * umpto s / eske ett r o> es' g ^ nasa-esa equipment requires labor-intensive, sophisticated considerable expertise, which is reflected in the cost of the equipment.

The invention series! Our aim is to overcome the shortcomings of known devices and <v <1 'c, .m' »eeb 1 'stbb cm. U. s í u e λ u vs> ke '\>

number of fluid handling and actuating elements between unit and its mounting requirement, \ t imi * v x ·. v. ne e \ en uvkdübht \\ ps t 1, \ í> Jj 'j <ö' \, v may be solved with fewer parts and greater reliability, and the test <> ir 'K is t'M'aesx. i's.eu-e'm you can

A sm round.t>' _? <e'n'.n it3vgclc.t \ .tomgondat the matsogabar. known un ..like dad s \ tp ', tdk. which consists of an intermediate structural member moving between two stationary structural elements, the basic principle of which is the sampling of the test substance in a defined, accurate dose,

Accordingly, the inventive idea has been based on the discovery that if the central element of this known simple structure sampling device, consisting of few components, is not only: capable of separating the desired amount of sample, but also of additional structural elements necessary for performing sample measurement. also in this moving member, okay? also allo members that surround the moving member -vpáto? In addition, with the addition of portions facilitating the execution of the honeycomb, the relative displacement of the moving broad relative to the stationary members can be utilized for sample technology locations, e.g. dilution. for measurement, $ tb. . i í mér uv I I I kis kis man man man man man kis man man man man man man man man man man man man kis man man man man man man kis man man man man kis man kis kis kis kis kis kis man kis kis kis kis kis kis o o vg κι c - y i s' * to perform the measurement with the desired accuracy, so that the task can be solved.

A. In accordance with its object, the multifunctional unit of the present invention is for the treatment of specimens containing a liquid component, in particular for the evaluation of blood samples, which has a lower standing member and a higher standing member. inserting between the lower stationary member and the upper stationary member a sampling subassembly having a movable moving member relative thereto, the movable member of the sampling subassembly having a sample passage, and the upper standing member having at least one upper sample passage and / or the lower stationary member has at least one lower sample passage cooperating with the tnmia-stopping flight, the upper stationary being a broad upper zero airplane and / or the lower stationary member's lower sample passage-while). x 'κ. v - 'dbar - ov nouii' m ka .A is connected to a reactor assembly comprising one or more preparation chambers in the vicinity of the outer oiduks of a 1 c.oy 'I, and a mobile member from the preparation chambers of the reactor assembly the atoms extending to the upper boundary surface are sewn, while the lower stationary member has at least one control passageway that can be connected to the \ aoe \ conveyor assembly, the movable member extending between the upper boundary surface and the lower boundary surface of the movable member; having an outlet cross-section with an outlet cross-section and an outlet cross-section with an exit cross-section to the lower boundary surface, the upper stationary jigsaw or the reactor assembly having one current conducting member and the lower standing member having another conductor complete with \ 1 'v oc fobkifo vgwti? oraboi otm et mm 'v tm ^ ckh οχ', yv · <>

the lower stationary member of the upper sample member and the lower stationary member have one lower specimen passage flight while the lower stationary member also has one lower millionth passage flight and the upper sample transfer flight and the lower sample passage flight are below the upper stationary member and arranged in a member v. v 'eo so óm ci' k ml o. gymnastics <, ' ¹ oUnly m- \ g to \ ¹ fe m gn \ oo se is provided with a higher nnary leveling passage, and in at least one resting position of the movable member, both higher. or a lower member of the sampler assembly having two lower sample passageways and, in at least one resting position of the movable member, each lower sample passageway being in fluid communication with the moving member.

In another embodiment of the invention, the drive member is provided with a movable member and, optionally, near the outer side of the lower stationary member, in the vicinity of the mm passage passage or near the outer side of the upper stationary mg. ', w o sO'k \, u el h? Again, in a different embodiment of the multipurpose unit, a plurality of different gauges are arranged in the node. Each measuring passage has a separate measuring cross-section and each measuring cross-section has a different through-opening.

In a further embodiment of the _{métözó.nábaa:} measuring passage located nferökeresztmetszető & moving member has an upper bounding surface of the moving member or the lower boundary facing the lower surface of the stationary member facing the stationary member .felsőbb.

For the multipurpose unit, it is advantageous if the sampling organ is able to correctly contact the upper or lower member with a thin pipeline, preferably

THE . wi \ - u ni) \ t jcvcc '? .n »' s ele \> rk co, mree 's, j, m <Jm these spaces mean that due to the novel design, the desired amount of sample can be removed and the measurement can be done in one Merged unit so that while. the. multipurpose unit size ···· compared to devices capable of performing similar tasks - decreases, multi-purpose unit tasks increase and bandwidth of samples to be tested Can also increase k \, ns un nm a, Ivxel? ew> nth kd, - es mt · '· * em'> e ¹ if you have structural elements for moving dances, so the number of rain members and valves is reduced, the ktfen / o system will be much simpler and clearer. This in turn reduces the maintenance pt'd, mmo itu the more cm malmde-d ovvferd atoxagt females.sk as? Neghih.fete, ^, h, plateau? ;> diminishes Ö-dezodaha The present invention can be operated by an emfeg kóhseghmekomfeman.

It is also considered to be an important advantage, besides being suitable for scaling, the tip in the preparation chambers can always be produced in the same amount and the total amount of the prepared sample can be weighed, which makes the measurement results much more reliable.

Do you also have the advantage that the through-hole with variable diameter cross-sections can be further increased? the ability to use a multipurpose unit, since, for example, in veterinary applications, the optimal size of a sternal section can be assigned to different cells of different head causes using different devices.

Also, the construction significantly reduces the risk of breakage of the permeable opening of the cross-member tension and thus greatly increases the usability and capability of the multipurpose unit.

- 6 "

Another important economic benefit is that the short liquid pathways reduce the amount of reagent needed and the amount of energy required for operation, which is a useful penalty for the cost of cleaning, and I do not want to reduce the cost of this system. , nuz aL, y, oo our bear in more detail, In the drawing is

Fig. 1 is a side elevational view, partly in section, of a variant of a multifunctional unit according to the invention, and is a side view, partly in section, of a different embodiment of the knurling zone of the refining unit according to the invention;

Figure 3 is a side view, partly in section, of another embodiment of the multi-purpose unit of the present invention;

Figure 4 a. yet another variation of the sampling unit of the multipurpose unit according to the invention, in side view, partly in section.

V 1, jfoaa „t songwriter s / er, nn, Ψ ^ ΰι: egriek bemtetovnn uá shows an example of the use of a suitable \ er ts-amplator half. It can be observed that the multipurpose unit, 10 sampling units - in a manner known per se · It consists of 11 lower standing members, 13 upper standing members and 12 moving members located between them. In this case, the lower stationary member 1.1, the moving member 12 and the upper stationary member 13 are ceramic discs of the same size, and the moving member 12 is capable of rotation about its own axis of rotation. a, I I connected to a lower stationary member and 13 upper stationary members. Of course, this geometric design and material selection is not a necessary requirement.

/ 3 The rotation of 12 moving members is controlled by the actuator / 0, which in our case is a high precisionM '<'ti> etopt 'e ο? feji '>,''n.vA'pt.iomofe ⁵ raifolz'k

The upper member 13 of the sampler assembly 10 - in this embodiment. - 1.3 is a higher standing member '\ η> «. μ buw es «, cyW *. kea <\ <Pt \ 'íc, k ι ι, i in the lawn r * Today a preparation chamber and a preparation chamber 14b are provided. In accordance with the preparation chamber 14a and the preparation chamber 14b of the reactor assembly 14, the preparation members 14a in the upper stationary member 13 are five c-afxna, nug is the pre-14b * Laso in * et> l uvscabbába I fe evuor na trained. Channel 15a and channel 15b connect the outer side 13b of the upper standing member 13 and the inner side 13c of the upper standing member 13. and thus provide an opportunity for the reactor assembly 14 to be assembled as shown in FIG. the pre-emptying chamber and the preparation antenna 14b are accessible from the 12 moving members. The first stationary member 13 here has, besides the channel 15a and the channel 15b, the upper sample passage 13a. the sampler 30, in this case a rigid mandrel, being connected to the outer end 13b of the upper standing member 13. It should be noted that in the reactor assembly 14, in addition to the preparation chamber 14a and the preparation chamber 14b, any plow is further measured. n, 're-lent> $ / -rereen .- "-. mos mrene-reégu, the upper 13th ebo ns L' 'k is also associated with an additional channel extending between the inside of 0' 13c.

The moving member 12 of the sampler subassembly includes the sample passage 12a, as well as the working section 20. - optionally - -a 1? also a transfer chamber. In this embodiment, the gauge 20, the gauge loop, gauge 16 'and the gauge shoot are provided. The test passage 16 has an inlet section 16c extending to the upper boundary surface 12b of the movable member 12 and an outlet cross section 16c which opens into the lower boundary surface 12c of the movable member 12 and has a cross sectional area inside the passage 16 and having a passage. Also from a measuring passage 16 'having a shot' on the upper limiting surface of the movable member 12, an entrance kewmmeter, an exit cross section 16c 'located in the foreground 12 © of the lower member 12 and an inlet cross section of the lofe: and 16c. The cross-section 16b 'located between the exit cross-section 16b also has a through-hole 160' which is different in size from the loose-through opening of the pass-through 16. Of course, the 16 un>>> met un un un lo ’’ ere ere ere met met met met met met met met met met met met met met met met met met met met met met met met met met met met met met met; re * obz-re sreru re x're. χ x re \ ex ~ tewtl ro jtó.re Afeierereo.rt, mp, íc chpx-n, ct <-tóren, t lód akt.re're re4recre re - etherex're? re, í, <> x \ blood vessels πλχ'1. ο μΆγ.Αϊ o sxjtnreictxA c, re'tx0ren ts r.erenre / a ixüre-ccca cm reg feoreot acts on \ "reg 6,.;

A. The purpose of the transfer chamber 17, which is formed in a moving member 12, is to allow the transfer of the sample between the preparation chamber 14a and the preparation chamber 14 for samples which require contacting the sample with several reagents during preparation of the measurement.

Turning now to Figure 2, another version of the measuring zone 20 formed in the sampling subassembly 10 can be observed. Here, the measuring zone 20 comprises a single firing test passage, which for the moving 12? '-> re · s re ·, v Ίο xc.tíit.r uresde k.t \? Xlepp x'v:% - <rereffe 's cross section. However, it can be seen that while the entrance passage 16a of the measuring passage 16 is just in section

-8 is equal to tracolfo for the 13 upper standing members l $ a channel for the 13 upper standing members 13c.? cvi'K'ó'tfo, ι'ι η ί! Ι aUebb stands, 'lig lld \ cz de j raumsk, He be <Figure m e u. ms, mr.ets -et disk larger mhn a lo scale inc exit kems / imeís xae.

This is because in this configuration of the measuring zone 20, by gently moving the movable member 12, the passage between the channel 15a of the upper stationary member 13 and the inlet section 16a of the measuring member 16, i.e. the inner side 13 © of the upper stationary member 13 the aperture formed between the upper boundary surface 12b of the movable member is adjustable to a variable size, and here this aperture forms the through-hole 16d of the measuring transverse position 16b of the single measuring passage 16, where the sample i; \ w negmrien'h Λ uva ife.mg fits / em at the intersection of the moving jag 13 and the lower standing member, the exit cross section 16c of my diminutive 16 should in all cases be non-distal, connected to the lld leading passage of the 11 lower standing members. This can be solved if the outflow passage 1 has a sufficiently large opening at the intersection of the lower boundary surface 12c of the movable member 12 with the inner side 11c of the lower standing member 11 so that the exit cross section 16c of the test passage 16 is completely free from it. regardless of how the cross-sectional inlet 16a of the lower meter is positioned relative to the channel 15a of the uppermost member 13.

Returning to Figure 1, it can be seen that the lower standing member 11 also has four lower throughput passages 11a, near which, preferably, it is surrounded by the attooh 31 'lb outward. , e \ tH? di \ el kun nnuacra in the lower al te member I met the lld tezerlo flight ks' which connects the 11 lower standing members Ile minor diploma and 1 ih outer side, λ II lower standing member 11b on the outside side lld controller near passage tafelh.no is a 4v fvh transmitting unit for transmitting material in the direction of the measuring member 20 of the moving member 12 and the reactor assembly 14 of the upper standing member 13 using a differential pressure such as pressure or suction,

In order to measure the sample to be measured according to the volumetric impedance principle, in this version of the multifunctional unit according to the invention, one of the current conducting members 50, in the channel 15a and in the channel 15b In the 1W control passage of the member, the ode is provided with another current control member, while one of the current conducting members 50 and the other current conducting member 66 is to conduct electricity to the arrows 16 'or gate **' of the gate 16 '. measured in a nipple to enable measurement, pk in the through hole 16d of the cross-section 16b or in the through hole 16d 'of the measuring beak 1.6b'.

It should be noted bog; / the shooting test passage in the measuring zone 20 may be hired by any sensor, e.g. an optical sensor, and may even be provided with an arrangement in which a sensing means for measuring several physical or chemical characteristics is provided in one test passage.

In the embodiments of Fig. 1, the upper sample passage 1i, the flow passage 12a, the lower passage passages 1a are discharged into the lower zone 4i, and the measuring zone 2a passes through. shoot measuring passage 16 and measuring bulb, such as channel 15a and channel 15b of the upper standing member 1 through vertical openings in the position shown in Fig. 1, and the sampling unit 10 on the outside of the lower standing member 11b as a base, resting horizontally.

In the base position of the multipurpose unit,. As shown in Figure 1, it can be seen that the lower standing member 11 is the other miutaake / etho walker, the moving member 12, the mining passage 12a, and the upper standing member 13 'kx vt.in, <, vto μα, ^ s. 'Uuepx? t ív ev \ v'í v «vn Ucte / ot cne ^

Figure 3 shows a configuration of the pnutawtoh test unit p © \, m> 0, to provide the upper member 13 with a basic natrrse trace 13a, but the lower standing member 11 does not have at all the lower iris passage 11. The moving member 12 is provided with a sample passage 12a which is a y. mg. o vke teámé ', o fclnkts.be bcnurk.tb ftveh 1 t d3 íeA lower standing member kei datab I k, lying' ¹ 'mmt ufee vtó pnata úfe, xan ehendt, \ ca 3k.better member that given ee' © vtben n vm t *. feteel · © tataíavAC, cto mát "12a mmtatarto 'mu fe.ett be: a, .in û folvd Ί amrmesi .η, ν'. ^ ,,, ΓθΛ ,, Ί. ^. ίηκΛ'ΌΛΊ \ 1 m feAobb mmjautc , \ s> i, 'at'k eg'', ea 0' mntnc \ n, while. another stone passageway 1.3a has a stone sensing member in the rock.

A * fom ed a 'ab'ax <ü dter.n town o \ ar. Aumm.o did you eat grogee reviews but. ' the upper stationary member has no upper iris passage 13a, while the lower stationary member 11 has a lower specimen passage. The movable member 12a of the movable member 12 may also have an inverted 2J 'socket into the upper surface 12b of the movable member 12 having two vertical passages extending from the upper boundary surface 12b of the movable member 12 to the movable member brake 12b. dm n.íbn-0 © k-ltdeuhg The 10 mmtaxcfelme ^ cgxsc ^ teaphchxcteben is one of the 11 lower alpha members

-10 11a lower passageway passage and another I la lower passageway passageway. the miniature passage 1 2a meets a vertical projection of the miniature passage and is connected to a bed for fluid communication. One of the lower passageways of the lower standing member 11 is connected to the sampling organ 30, while the other lowering passage 11a is associated with the blood sensing organ 8Ö.

It should be understood here that the 10 sampling units of the multipurpose unit may have additional technological openings in addition to the visible passages; eg for storing and delivering a neutral liquid for cleaning channels traversed by samples. and collecting the washing liquid used. They are, however, of no interest in the subject matter of the invention and the operation thereof, so that they are not shown in the figures for simplicity,

Ά ,, '. Ονηη v ernf multipurpose' gweg rmd right ^ et a. í abten bommat, ktv tel · a ', A a'ap en more detailed, At the beginning of the analysis of the sample, the storage unit holding the sample is given the 30 min> and * etod ,, it would take a lot of 30mmtm, m <' ehri mima, then t - * u fluid transfer unit · - program of its own control unit. is activated and pumped through the sampler organ-13a upper .mia-through passageway-12a-sample passageway-11a lower sample & guided passageway to the multi-purpose unit 10 subassembly. When the sample reaches the blood sensing device 80, it sends a signal to the fluid transfer unit 40 which shuts off. At this point, the required amount of minus to be examined is in the 12a holding passage 12 of the 12 moving members of the sampler assembly.

When specifying the amount of sample to request the moving member 12 into the missile passage 12a, the actuating member 70 initiates the moving members 12 which slip between the upper stationary member 13 and the lower stationary member 11 to position the sample passage 12a just in channel 15a. Moving member 12: In this position, the sample in the sample passage 12a can be transported through the channel 15a to the preparation chamber 14a of the reactor assembly 14 via the fluid transfer assembly 40. In Preparation Mouse 14a, the sample to be tested meets the required amount of reagent and the expected reaction is completed.

Thereafter, the already empty blank flight passage 12a moves the moving member 12 with the aid of the moving assembly meow slides into the i5a. and below the channel 15a, if no further preparation is required, the measuring zone 20 will arrive. Depending on the physical size of the ingredients in the desired substance that is inhibited by examin, below channel 15a. arrives at a 1: 6 mcnuar with just the right paddle arrow. Of course, if there is a single measuring passage 16 in the measuring zone 20 of the moving member 12 having a measuring cross-section 16b within the measuring passage 16 between the inlet cross section 16a and the exit cross section 16c, only this single passage 16m can pass under channel 1: 5a.

In the case of a measuring zone 20, where a plurality of measuring passages 16 having a different bore permeable opening 16b are formed, the measuring zones 20 after the arrival of the measuring channel 16 having the desired throughput 16d and the anchoring of the movable member 12 - via the fluid transfer assembly 4 (1), passes downwardly through channel 15a and passes through passenger passage 16a into gauge passage 16a and passes through the fluid passage of the probe, e.g. the volume of the blood cells is counted by means of the current between the other conductive means 60, by the volumetric impedance method. The sample flowing downward through the gutter pass 16 reaches the exit of the gutter horse 16 where it then exits through the control passage 1 Id leaving the multifunctional unit 20 zone.

After analyzing the sample, washing liquid (not shown) can be used to clean the measurement., Es, _s nn 'tlxeo mimé can be started with cto / ev.U \ -> iMnedeterA. For this, of course, the moving member 12 of the sampling unit 1 (5) is restored by the moving member 70, and the miniature passage 12a is reproduced by the upper mitotic passage 13a of the upper standing member 13a, i. E fo> m, * wt muv-hm. rp, x,,, em, mn ^ ew ebb te? a ^ \ e * kel n - \ m-elo e>, 2 t.

After the time spent in the preparation chamber 14a, it is not the shooting gauge passage of the measuring zone 20 which slides under the channel 15a, but the moving chamber 70, thanks to its control, to the further chamber 17. The mfofe treated from the preparation chamber 14a with the first reagent is now introduced into the transfer chamber 17 by means of the fluid retention assembly 40, and the transfer chamber 17 so filled is moved by the movable member 70 together with the moving member 12 so that the transfer chamber 17 arrive under channel 15b. From the thus positioned transfer chamber 17, the treated sample passes through channel 5b to the preparation chamber 14b via the liquid transfer assembly 40, where it also meets the second reagent. After sufficient time has elapsed from the preparation iun of the i4b, the measuring zone 20 of the moving member 12 turns 16m below the channel 15b, and the measurement process is carried out as described above ...

- 12 If the measuring zone 20 of the multipurpose unit is as shown in Figure 2. then, during the mima analysis phase, the moving member 70 slides the moving member 12 so? between the uppermost stationary member 13 and the lower stationary antler 11, that the entry of <1 egyetlenοη U \ e ^f e \ above 1 p, '\ t cxabmv. \\ Ά <. z? x? ν 'k. The part which here essentially encapsulates the passageway of the code, just the desired wu'iu I When the proper passageway is formed, the moving member 70 locks the moving member 12 in a given position. and the sample is measured. The throughput opening Id itself is essentially the interaction between the inner side I3e of the upper stationary member 13 and the upper heat storage surface 12b of the movable member 12, so that the measurement is d mmmn the inner side 13c of the upper stationary member 13 and the moving member 12b. the upper boundary surface of which is ulene-mL., it should be noted here that the fluid transfer assembly 40 has a plurality of IM control passages ^{? 1?} k'xoer i'iAcx the 'mmxlo urota,' oke \, rm-le ' the ".,? fen n ⁿ m inn '>x'i' tbo. J vz eg '--u íu >> ^ 1 edxoe <.' η · ¹ ee · 'o'<, gtm e · 't'o'm m j.

which is located in the 11 lower standing members. It is understood, however, that the pirate passages associated with the fluid transport unit 40 may be located not only in the lower stationary member 11 but also in the mobile horn 12 and the upper allele member 13 and even in the reactor assembly 14.

The multipurpose unit according to tduhuzov is well suited for sampling and measuring blood cell counters in particular, but is suitable for general particle counter sampling and mefe (, ûu / Cinben toritrv tchia 'ti asm <s

Claims (9)

A multifunctional unit for treating samples containing a liquid component, in particular for preparing a blood sample evaluation, which is provided with a lower standing member (11) with a higher standing member (13). and a sampling subassembly (10) inserted between the lower upright member (11) and the upper upright member (13) having a movable moving member (12) relative thereto, a moving member (12) of the subassembly member (10) having a sample passage (12a). ) is provided while the upper stationary member (13) is provided with at least one upper sample passage (13a) cooperating with the extending passage (12a) and / or the lower stationary member; Having at least one lower passageway (1a) cooperating with the sample passage (12a), a. and the upper mandibular passageway (13a) and / or the lower mandibular passageway (11a) of the lower standing member (13) communicating with the sampler (30), indicating that the upper standing member (13) associated with one or more reactor assemblies (14) extending around the outer side (13b) of the outer bath (14b), and in the upper alloy from the preparation chambers (14a) of the reactor assembly (14). (12b) are provided with guide channels (15a, 15b) up to the upper control member (12b), while the lower member (11) (11) is provided with at least one control passage (1 Id) for connection to the fluid lake transport assembly (40). , the movable member (12), along the passageway 112a), the intersection between the upper fish »portion (12b) and the lower boundary surface (12c) of the movable member (1.2) entering the upper boundary surface (12bí knofool). a set (shoot) and a measuring zone (20) having at least one gauge passage (16c) having an outlet cross-section (16c) extending to the lower boundary surface (12c), the upper stationary member (13) and / or the reactor assembly (14) is provided with one current conducting member (50), and the lower diagonal member (11) is completed with another current conducting member (l). 2c The multipurpose unit according to claim 1, characterized in that the upper stationary member (13) of the sampling sub-assembly (1) cooperates with one of the upper sample passageways (13a) cooperating with the mine support passage (12a) and the lower stationary member (11). the cooperating sample passage (12a) also has one lower sample passage passage (son), and the upper passage passage passage (1.3a) and the lower passage passage passage passage (fia) in the upper stationary member 115) and in the lower stationary member (I1) arranged. The multifunctional unit according to claim I, characterized in that the sampling unit (10) is a t-teobh Τ '.-Mgi.i te 11 ke omol · Ite ^ -ob mmt space c / ete jar.me te, te '· \ ,, u for the mosaic tag do it -1. And at least one at rest position, both upper sample passageways 03a) over the sample passageway (12a) of the movable cut (12), in a suitable connection therewith. ~ I mentiont 'eat \'brv.eb> vgvag ua \ ú jdfemsme, bog \ annknéteh KAmpscg 0O ^X lower lower member 01) is provided with two lower sample passages (1a) with at least one resting position of the moving member (12) and each of the lower sample passageways is located below the sample passageway (12a) of the movable member (12a), with which it is in fluid communication. Multipurpose unit according to one of claims 1 to 4, characterized in that it is provided with an actuator (70) connected to the moving member (12). 6. An antenna multifunctional unit according to any one of claims 1 to 5, characterized in that the lower stationary member. (11b) near the outer side (11b) of the sample passageway (a), there is a blood sensing organ (80) located near the mimicry passageway (13a) in the vicinity of the mute carriage (13a) around the femur Jfe member. ?, 1 ...- 6. Multipurpose unit according to one of Claims 1 to 3, characterized in that the measuring zone (20) is provided with a plurality of different measuring passages (shoot, 16Ί). 8. The claim 7, characterized in that it is characterized by ht ^? <'cate ·' »'n \ ojun tők *' '»> each having a separate cross-section (16b, 16b \), and each cross-section (10b, 1b ') having different throughput openings (164, lo'). 9. Az-L. A multipurpose unit according to any one of claims 1 to 6, characterized in that the feco netbcbr / kci'o me.c.oat has a headset: 160 is an arc-u, g.a.7 'is a superimposed member 113,! .lété. at the upper boundary surface (12b) of the rain or at the lower boundary surface (I2e) of the moving member (12) towards the lower stationary member (.VI). 10. A multipurpose unit according to any one of claims 1 to 3, characterized by a thin pipe, suitably Kv ά v *, for the upper stationary member 13) or for the lower stationary member 11, preferably a needle.