PL88988B1 - Method and apparatus for measuring particle concentration in a fluid suspension of particles [us3733547a] - Google Patents

Abstract

The apparatus includes (1) a Coulter type particle analyzing device for producing a particle pulse each time a particle is in a sensing zone, each particle pulse having poorly defined leading and trailing edges and a duration related to the time the particle is in the sensing zone, (2) electrical circuitry connected to the output of the particle analyzing device for producing, upon sensing each particle pulse above a predetermined threshold level, an output pulse having a selected clearly defined duration established between (a) a clearly defined leading edge of the output pulse occurring at a time substantially equal to the time of inflection of the slope of the leading edge of the particle pulse and (b) a clearly defined trailing edge of the output pulse occurring at substantially the same time that the instantaneous value of the trailing edge of the particle pulse falls below the level of the instantaneous value of the leading edge of the particle pulse at the time of inflection of the slope of the leading edge of the particle pulse, and (3) apparatus for measuring and displaying the duty factor of a train of the output pulses. [US3733547A]

Description

The subject of the invention is a method and a device for generating pulses dependent on the concentration of particles in a liquid suspension. From the United States patent (No. 2,776,159, a method and device for determining the concentration of particles is known, in which the measure of concentration particle in a liquid is the ratio of the time it takes the particles to the total flow time of the suspension through the window of the device. This solution is intended especially for determining the dust content in the air, but is also suitable for determining the concentration of, for example, blood cells in the electrolyte or industrial particles in various liquids. The window size of the device in this device is small enough to contain one particle at a time, but long enough that the time during which the particle is neither completely inside nor completely outside when entering and exiting this window, and was to skip. particle in the window, the device produces a particle pulse which is then amplified by a high gain amplifier. The result is a series of particle pulses of equal amplitude and duration proportional to the time the particle passes through the window. Basically all durations are the same. As the particles pass through the window, the amplifier changes from saturation to cutoff. The output of the amplifier is connected to a meter that responds to the DC component of the output current. This input may be voltage or current depending on the type of meter or averaging used. The meter is labeled in units of concentration. Losses due to the presence of more than one particle in the window at a time can be compensated by the concentration of the meter scale for large concentrations. The length of the window in this device must be much larger than the average particle size, because for long windows the relative the duration of the forehead and trailing edge of the pulse is negligible compared to the total duration of the pulse. However, the use of long windows causes many drawbacks, such as a reduction in the size range of the particles to be measured, a reduction in the useful signal from noise, a reduction in the level of particle concentration in which particles pass through the window simultaneously. In addition, long windows are easier to clog and are difficult to clean. Known electrical systems that work with the Coulter particle analyzer, when used to measure the concentration of particles in a liquid suspension, do not provide £ 9,988 for excellent measurement accuracy. The detection zone in the area of the aperture is small in these analyzers for the use of such electrical systems. The usual length of the aperture in the Coulter aperture is equal to or less than its diameter. Since the particle pulses from the Coulter aperture are relatively short and have amplitudes proportional to the particle size, this clogs the amplifier with a large amplification rate. Rectangular particles may not give satisfactory results. Larger amplitudes of the pulses sweep from tough particles may cause dJujESaym sygriaphs to last longer than other particles causing pulses of a smaller amplitude appearing in the seal not only pifc This results in a favorable limitation of the measuring range to particles whose dimensions are much smaller than the length of the aperture. Moreover, in the case of using Coulter sensors, there are distortions in the length of the pulses resulting from the uneven distribution of the electrical field in the aperture and from unequal velocity. fpjaftptywu; sawdes ^ ny..electrolytic at various points the slots. An object of the invention is to develop a method of deleting Lateaai tapes from k ^ c ^ traoi; particles in a liquid suspension, in which the information about the concentration of the particles is independent of the particle size and the transient "HWttay". A further object of the invention is to develop a device for generating pulses dependent on the concentration of particles in a liquid suspension, free from the disadvantages known to date. devices, in particular ensuring the elimination of errors, wno- S ^ aycfe pegaa pattering of particles in the slit p $ t ^ rze w & mwtw * 'fr4yn.te Press odipjpwiediuie gauging. CA this was done by, tc ^ fce n £ ridge fe? - c & go produced by , cz ^ jsjtfee impulse wyna- Gift m * »* g ^ me ^^ take o ^ esfoae points, pcz ^ Wm fcwlrty these sa Rr ^ ejsuwejte batch, yourself W * bind * in ^ watWH sie, signal © * reJJla; iacy second gjpcoj4pa imjwjlicii wytwc * reojae, gQ pcz ^? time & e, ptf ^ l & uj * WA l ^ rz ^ wp ^ zo ^ ifcffiuls. with & a help of a ukla- cta mQ $ & WWte * ^ a ^ t ^^^ m, porółw ^ uje sde cl ^ low value & t ^ l & ywmSZfr vnputeu with 9? # en $ a whole value im ^ wlsu. produced * gb $ mi c * a £ fce, oifcre & a sia to burn cwejw * jfo 'iWfey converts two points - HA #a feaódego im ^ uljsu, produced by the time - iftfok rolls sia impuj & y, fetorycU duration times ^ f * ## W? «P ^ * S« te * l <** lSW in the range cag ^ e ^ <* r% WAfl «* WSSflitW ^ y va independent j £ -« Wuttil4 'imcuteftw in ^ & io / s, Purpose. has invented o ^ ia ^ ato r ^ W ^ fet $ XZS & tQ ». -U WWaflgenie w ^ & cfttfg inventions with ^ ie ^ n # y- iMaffiKli 4w & * csasflfofe eWtowAwy icompa ^ tipy ajUbjp RS for generating pulses with tri-times in- ote? * Sw ^ ° Jsófrai reverted times ^ t ^ rzonyck for., part of the pan 4 msMMfrto iftiezaleinych c4 amlplitudes of those OtfafeMck $ H0pR # sifo #. Depending on this, Htfae cjiajailtkujeystic3ne. the impulse points have been determined by the CSWjf and the device contains the appropriate * zyfirojelptcwane teams for determining these points. Mpz & a, for example, determine the time line between the two points located on the crest of the pulse at the height of a certain part of its amplitude. Another possibility is to determine the temporal prjcctltlt between the peak *! * Of the pulse and the point on the rear edge * at a certain part of the amplitude, as between Ptor and Klys, the last inflection points of the impulse, altoto between the transition point of the leading edge of the impulse and the point on the trailing slope at which the momentary wait of the wave and B will give the nlzel vw of the instantaneous angle the index corresponding to the inflection point of the pulse front. The subject of the invention is presented in ftfjyfeladft; I invoked the drawings in which? q fig. and crafdrtswla § crafdrtswla § ctematyK? are not cut by jCoulter with sharp edges in the cross-section and showing equipotential Djhii, Fig. B - the shape of the impulse caused by czabtke prjtfc ^ is c ^ P »^ * zc $ eljne et lig. I, Fig. 2A - 2 & acA ^ n ^ a.tyicjeme Coulter slit with rounded edges, in cross-section and with an erasure of the lily of the quirk and tine, Fig. A © - pulse shape caused by a particle passing through the slit in Fig. 2A, Fig. 3A - a diagram of iblos Iwwa of indignation by Jazku, fiig. 3B - in this section of the SUMM C; 5 sau the shapes of the limbs appearing at individual points in the diagram in Fig. 3A, Fig. 4 - a block diagram of a part of another solution of the device according to the invention, Fig. 5A - a block diagram of yet another - uraadsend solution according to the invention, Fig. 5B - in the same scale of all pulse shapes in a broader range the point of the system of Fig. 5A, Fig. 6A - the block lehema of another solution related to the length of the invention, Fig. tf @ k - ksz system af * g. GA, lig. 7 - the shape of the essential impulse produced by the analyzing system, showing two points determined on the impact of this impulse, fig. 8 - achetna * W © iko »45 of another solution of the device of the defect of the invention, fig. 9A - in the same the doublet of time was signaled in particular points of the diagram with ifg. ft, fi ^ g. ftB ™ continuation of the graphs from Figs. & A, Fig. 10 - * r- Signal biscuit of the second derivative of the partial pulse in the device% Fig. a, Fig. 11 - shapes of the superimposed »a network of two signals that are compared in the device, the one in fig. * IA and 2A ptroedsibel the aaezellan-55 ml plates in Oaujter's ezattek analyzers. In the five of the lft from Fig. TA, there is Ift ii 14 slots 1 & sa oatre. If the electric water is equivalent to an electric drink, it is blown out at night, and there is no blows? 9 J * Q1 ^ i sjpGwodowó 3mia ^ feaataJtu imputyu y% wrar «a» ego bad ^ imftujs "breaks the line in Fig. 1 ©. A village of impui & s produced, however- WZ & transition c «astiki wadiui *** ft8 * -aie asa fdofclafcjie * & l« * toutfsa * ^ z. ^ Ig. 2A Jtrwsk ^ ea && 8 «c2jeriinx £ 4 panaoteftglone. / Uri <& '«fe« ripc | ta ^ naj- ^ 4n € 3rtto ^ uzt ^ t ^ f) a (jtmn ^ Bxa, irsf & OTriftffzezone sa ^ jc ^ ez * 4taik% s ^^ ^^ myj ^ estlfis6wi »tóv doWNteflfci ** # ** jky -ze., tw9za »ro- * .daa * s nwnjw» 0 ^ fmai ^ - «Q ^ nytQ, pwKtoie i, / rear tfteWlwrrtwyl ^^ pwez * $ a ** C. ¦ i.iNawmMi'Hitu i ^ .ftfujg ^ yynwWiruyM6r ^ zaw-, ^ yctefi ^ w * ptefl * ^ m - WSWtfiauwÓBWfcas ^ vi * wttglgiitflone, wr ^ luantfpu 3-WrtgdjyfcutDfjko? ultbrnfjk? «Da Jt ^^ t aiibUadnie ^ welcomed ^« v ^ i ^^ a ^^ cziUad ^ pol9ii ^ iipq »tf &BUft; Jkoiii | eaQ ^^ eoJrtira ^ nnfeasaiz | £ l ^ * cÓMtti ^^ ¦ ittTPffOwtóz ^ i ^ rw ^ aicEi »« p - 32 aiodtffeow * g (tt «« p * ac- -ittiiacza. ^^ yseoalyi ^ fH iw * fe * 6 4aod * rona / a .aa ^ w ^ Jnria Akonnpauaitijra ** 4V% ^^ * Olt ™ wza a # »al; i * $ * # aio- - ot tyiiDCK. W« nffcttfal &) & MU ^^ V4 * u 3 ^ *; piTiBd ^ i ^ -Mity ^^ edawmy. Jaat / itfia v: & * ifefidtniqtaceg0, ^ j ^^ ^ * tfteflafc »a sediment * Ata3 ^ (€ wjaakyjKainfigoiiW ^ €» doo «ttechf, 1tetfK« ptoariCaaieooiiiogidcur, S ^^ Hey ^ st ^ elected ^ do \ ^ * wlsotzogrtjrawia ^ - # £ 2 # jpriz4Giagteia; iropafclfrw. Slopes, ex JM / mnnlnryan ^ \ »trfS2x« spil- ^ ta ^ y: ^ j ^ A «^^ w na - ^ JWteo ^ oKawaatorfrotf *: wti * tf * yite * w0fc moato- - ^ tpe ^ iparitefa * Lq ^ F with ii «. , aB o vM * uH & 4 jfcafcgg? i jMljoMiji digi ^ lgrgyW ^ i «e» li- s * le ^ ira | ifcyaa ^ 35j * ^ 3g * mtettiareml% natari »» «fc ^« Wl ^ O0rtfiy- •• # « - * rxxpao (t * «* gSfr i, awwrasirarl * W» ^^ dflfea dotiifciLipurfl iiiiIiiiHi ^ iiiiiAiia aayflgHWftefeWa- ii ^ i ^ oi ^^ ytfctoyii * i »mit mm« tetsl # vwi «& ^ l ^ * 8. ^ pBaatttCttffiiliBjra ^ I yi 72 40- * Ma »wy. **« & Jgftawflr »wy d ^ fflfswBtWfrl ^ PP ^ a- uupr ^ aeoda ,, wrthi ^ m ^ fl« teu <) * a4% What jfefie ^ to ^ The whole »this * awfnian ^ 45 device is accomplished with this device AnaliaaitDdr Coultar is composed and composed as j» |) (reign, with ^ «zujnJka Hl WAl ^. 5--14 inclusion; 'if ^ - ^ a ^ describe ^ andadiz ^ nerja , .pt ^ ewodent 5- ^ 20, until uWbdu? 5 ^ 2A, ^ w ^ ia ^^^ ^ naewodein! ^^ *% yójoteataijacego ^ sftladu S- ^ 24, put in 'jjirij ^^ - ^ 80 to one of wet) sc na ^^ cip ^^ ^ n ^ dzy-Krz ^ an ^ | t JL t, na specimen * a | zl € r Sf-44 * lin- ^ «^ v4wu. ^ pftaje ^ ^ fe * pny w * SivkfiictC t ^ W, on ri < RTI ID = 0.0 &gt; cable ^ 5444i r \ Anaai ^ toc Coi * 4 € ra # be ^^ «# aqu ^ ^ iiiejaiz« w (* ti ^ iyfa # g »eg, jpgzmWfie ^ with ^^^ len ^^ etotofiic, pray with which iw oGfeytipranym 4? ^^ ^ i4MM »ia« «« tz «ajn ^ | e ^^^ na ^« gi 4Asi «« riMilQ ^ 4 ^ 4 ^ || ^ iiif ^ i mii ii i liiKiiiI llBiililllu nu i wflp6 ^ S ^ lft.iwaaxeac- '\ »* aotiy / iiIa w & lMuM ^ *** ^ sequence of kipu OBÓw whose afmpdiftuidy are essentially ml ^ MfiNMilm r irr ^ TrrrrnlrrfL" ^ rftfr *: n - ^^ T, -1- vj »y ^^ poegftft7 »wlinei i ^ jptógych, czgsy ^ tjiwLJiia sa ^ rtw» q »deztiioai | ^^ i * w * awtótoLa <-« ^ WU; tyc ^. ^ npoilfl6wripTtakes «it» wrav <* ^ »3 fiig ^ SB , pos. ohwile «z * aso- cLgzj ^ tók i *« »ieedflnQfcx \ 4su. ^ tJWf ^ liy & pi» rgft ^^) ittrtwwie <-4o, qktodu., ^ - 22 Pii ^ en

Claims (3)

Claims 1. A method of generating pulses dependent on the direction of liquid particles, suspension, including the passing of the liquid suspension through the zones of the mouth of a woman, where the detection zone * has an imala dhsgosc in relation to its strength, the dance covers areas with an undefined response "to the appearance of a particle", which is much larger than an area with a certain one: the response located in the middle part ** of the tetretfa 'lecture "ywandai" and the production of isy-and junctions corresponding to each of the detected particle, as a result of * kAcfepz of these signals' is \ imipufeenv: * 25 o dhagosct depending on the zone length * J detection d from the code of the particle, in this stretch; characterized by, i% -in the ridge of each 4m | pMi «l £ defines ard ^ ntwo ^ geoma * tric ^ ie cJdefined- points, including points -te sa; -shifted ^ relative ^ demt 'eiebiv in time, a * signal is produced specifying £ -the path ^ derivative of the im-. pnlato double by iczaatfcfct the processed impulse is sampled using the system® ipr ^ bfcflfwa- ^ with -zapartrietywm, compares} «unchanging value'4, swarm * owaxie ^ .fim ^ mlau}. lówa-values impulettos generatedafconedorfpjze * spell <stflc ^, 'length is specified: "interval of the time • between- determineddorna ^ iioWaKO * d ^ o * Timp ^ U -product * »eaa ^^^faceesielfe« pirfliy, whose Hrzasy lchhy-way "Y € deza-od te ^ -piz« feiato \ ^ za & Qwego, ^, ora * -which amfcttudy are itiamfr & rmod input pulses. 2. rSpmrfte vadlHg ^ tt1.1 wntimnfrtyin, with two ts of siphisna tsdtóirtrni of mercury on the slopes of each [4 m]; p * istt: wyltSfr ^^ war-., toó & shwifowa eysoatow ^ of the designated panfciów ^ jeetarusiatena; czefaia ^ values- malksyi- mainej sygraalit1: 3.: and Methods of claim 2, including: for the determination of hdwu *; geemetry; of specified points * bring the-ImpalsL produced by the densit particle 'to' likaao ^^ delay and up to a number of dragging and suppression, delay ^ -im ^ t pals and ^ uklaikdeiicco-inducing ^ im- pu4 ** & with an extended impufts-dwD part of a certain ' the value of its original anicflitude is shared