CN104865375A - Debugging method and device for measurement positions of reaction cups - Google Patents
Debugging method and device for measurement positions of reaction cups Download PDFInfo
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- CN104865375A CN104865375A CN201510213695.6A CN201510213695A CN104865375A CN 104865375 A CN104865375 A CN 104865375A CN 201510213695 A CN201510213695 A CN 201510213695A CN 104865375 A CN104865375 A CN 104865375A
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- reaction cup
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N33/00—Investigating or analysing materials by specific methods not covered by groups G01N1/00 - G01N31/00
- G01N33/48—Biological material, e.g. blood, urine; Haemocytometers
- G01N33/50—Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing
Abstract
The invention discloses a debugging method and device for measurement positions of reaction cups. The method comprises the steps that a signal receiving unit receives light signals emitted by a signal emission unit when reaction cups move to regions to be measured and transmits the light signals to a processor; the processor determines reflection cup side wall positions according to the light signals; the processor determines reflection cup data acquisition regions according to the reflection cup side wall positions. By means of the method and the device, the reflection cup side wall positions are determined through the light signals, the reflection cup data acquisition regions are determined according to the side wall positions, the data acquisition region positions determined according to the side wall positions are accurate, the selection of the data acquisition regions cannot be affected by geometric errors of each reflection cup, and accumulative errors can be prevented, and measurement results are accurate.
Description
Technical field
The present invention relates to biochemical analysis technical field, particularly relate to method and the device of the debug measurement position of reaction cup.
Background technology
At present, domestic Biochemical Analyzer employing code-wheel synchronously recognition reaction cup is tested, also namely starting point is determined by initial reaction cup, the position of test is precisely offside the closer to the middle part of reaction cup, distance between every two reaction cup is certain, thus after determining starting point, stroke is constant, but, because reaction cup is difficult to the geometric error avoided, and current Biochemical Analyzer does larger and larger reaction cup quantity and gets more and more, when reaction cup reach some time, following problem can be there is: multiple reaction cup is placed on the holder of code-wheel, holder by code-wheel identifies that initial reaction cup is to determine starting point, next reaction cup is identified again according to the distance between every two reaction cup, because each reaction cup exists geometric error, the error of thus accumulating can be increasing, measurement point is even made to fall the edge of reaction cup, measurement result produces large fluctuation, badly influence the accuracy of measured value.
Summary of the invention
Fundamental purpose of the present invention is the selected of the reaction cup measuring position solving biochemical reaction instrument, improves the stability of measured value.
For achieving the above object, the method for the debug measurement position of a kind of reaction cup provided by the invention, the method for the debug measurement position of described reaction cup comprises the following steps:
When reaction cup moves to region to be measured, signal receiving device receives the light signal launched from sender unit, and by described optical signal transmission to processor;
Described processor determines the sidewall locations of described reaction cup according to described light signal;
Described processor determines the data collection zone of described reaction cup according to the sidewall locations of described reaction cup.
Preferably, described processor determines that according to described light signal the step of the sidewall locations of described reaction cup comprises:
Calculate the changing value of intensity level in setting cycle of described light signal;
Described changing value and setting value are compared;
When described changing value is greater than described setting value, judge that described light signal passes the sidewall locations of position as described reaction cup of described reaction cup.
Preferably, when reaction cup moves to region to be measured, signal receiving device receive from sender unit launch light signal, and by described optical signal transmission to processor step before also comprise:
Obtain the distance between the data collection zone of described reaction cup and the sidewall of described reaction cup, and by described Distance Transmission to described processor;
Determine that according to the sidewall locations of described reaction cup the step of the data collection zone of described reaction cup comprises:
Described processor determines the data collection zone of described reaction cup according to the sidewall locations of the corresponding reaction cup of described Distance geometry.
Preferably, described data collection zone is the central area of described reaction cup.
Preferably, when reaction cup moves to region to be measured, signal receiving device receive from sender unit launch light signal, and by described optical signal transmission to processor step while, also comprise:
When reaction cup moves to region to be measured, signal receiving device receives the pulse signal launched from sender unit, and by described pulse signal transmission to described processor;
Comprise determine the step of the data collection zone of described reaction cup according to the sidewall locations of described reaction cup after:
Described processor, according to described data collection zone and described pulse signal, obtains the compositional data of the determinand in described reaction cup.
The present invention also provides a kind of debug measurement location means of reaction cup, and the debug measurement location means of described reaction cup comprises reaction cup, code-wheel, rotating disk, sender unit, signal receiving device, processor:
Described reaction cup is placed on described code-wheel, and described code-wheel is fixed on described rotating disk;
Described emitter and described receiving trap split the both sides with described region to be measured, described sender unit is used for utilizing emitted light signal, described signal receiving device receives the light signal launched from sender unit, and by described optical signal transmission to described processor;
Described processor is used for the sidewall locations determining described reaction cup according to described light signal, and the sidewall locations of described reaction cup determines the data collection zone of described reaction cup.
Preferably, described processor comprises computing module and judge module:
Described computing module, for calculating the changing value of intensity level in setting cycle of described light signal;
Described judge module, for described changing value and setting value being compared, when described changing value is greater than described setting value, judges that described light signal passes the sidewall locations of position as described reaction cup of described reaction cup.
Preferably, described processor also comprises acquisition module and metering module:
Described acquisition module, for obtaining the distance between the data collection zone of described reaction cup and the sidewall of described reaction cup;
Described metering module, for determining the data collection zone of described reaction cup according to the sidewall locations of the corresponding reaction cup of described Distance geometry.
Preferably, described data collection zone is the central area of described reaction cup.
Preferably, described sender unit is also for launching described pulse signal;
Described signal receiving device also for receiving described pulse signal, and by described pulse signal transmission to described processor;
Described processor also comprises data processing module;
Described data processing module, for according to described data collection zone and described pulse signal, obtains the compositional data of the determinand in described reaction cup.
The method of the debug measurement position of a kind of reaction cup provided by the invention and device, the method for the debug measurement position of described reaction cup comprises the following steps:
When reaction cup moves to region to be measured, signal receiving device receives the light signal launched from sender unit, and by described optical signal transmission to processor;
Described processor determines the sidewall locations of described reaction cup according to described light signal;
Described processor determines the data collection zone of described reaction cup according to the sidewall locations of described reaction cup.
The present invention determines the sidewall locations of described reaction cup by described light signal, the data collection zone of described reaction cup is determined again according to described sidewall locations, so, the position of the described data collection zone determined according to described sidewall locations is more accurate, the selection of data collection zone can not be affected because each reaction cup there is geometric error, and then can not cumulative errors be produced, measurement result is more accurate.
Accompanying drawing explanation
Fig. 1 is the structural drawing of an embodiment of the device of the debug measurement position of a kind of reaction cup of the present invention;
The sender unit of the device of the debug measurement position that Fig. 2 is the reaction cup shown in Fig. 1 and signal receiving device schematic diagram;
Fig. 3 is the schematic diagram of sender unit and signal receiving device in Fig. 2;
Fig. 4 is the part-structure schematic diagram of the device of the debug measurement position of reaction cup in Fig. 1;
Fig. 5 is the high-level schematic functional block diagram of the processor of the device of the debug measurement position of a kind of reaction cup of the present invention.
Fig. 6 is the schematic flow sheet of an embodiment of the debug measurement position of a kind of reaction cup of the present invention;
Fig. 7 is the refinement schematic flow sheet of an embodiment of step S20 in Fig. 6;
Fig. 8 is the schematic flow sheet of the acquisition data collection zone in Fig. 6;
Fig. 9 is the schematic flow sheet obtaining determinand composition.
The realization of the object of the invention, functional characteristics and advantage will in conjunction with the embodiments, are described further with reference to accompanying drawing.
Embodiment
The device 100 of the debug measurement position of a kind of reaction cup provided by the invention.
It is the structural drawing of an embodiment of the device of the debug measurement position of a kind of reaction cup of the present invention referring to figs. 1 through Fig. 5, Fig. 1; The sender unit of the device of the debug measurement position that Fig. 2 is the reaction cup shown in Fig. 1 and signal receiving device schematic diagram; Fig. 3 is the schematic diagram of sender unit and signal receiving device in Fig. 2; Fig. 4 is the part-structure schematic diagram of the device of the debug measurement position of reaction cup in Fig. 1, and Fig. 5 is the high-level schematic functional block diagram of the processor of the device of the debug measurement position of a kind of reaction cup of the present invention.
The debug measurement location means 100 of described reaction cup comprises reaction cup 1, code-wheel 2, rotating disk 3, sender unit 4, signal receiving device 5, processor 6.Described reaction cup 1 is placed on described code-wheel 2, described code-wheel 2 is fixed on described rotating disk 3, described sender unit 4 splits the both sides with region to be measured (sign) with described signal receiving device 5, described sender unit 4 is for utilizing emitted light signal, described signal receiving device 5 receives the light signal launched from sender unit 4, and by described optical signal transmission to described processor 6.
Concrete, the mode that described reaction cup 1 moves to described region to be measured can be rotation, namely reaction cup 1 is arranged on described code-wheel 2 (described code-wheel 2 is mainly used in the kind of the internal solution distinguishing described reaction cup 1, a described code-wheel 2 there is the described reaction cup 1 of multiple built-in same solution, each described code-wheel 2 is provided with on the holder 2a of accommodating described reaction cup 1) on, described region to be measured is turned to by described rotating disk 3, this advantage adds survey for circulating, one crawler belt can certainly be set, reaction cup 1 is via crawler-tread extremely region to be measured, two kinds of embodiments of the present invention are only both this, other described reaction cup 1 is sent to the mode in region to be measured all in protection scope of the present invention.Described sender unit 4 can be optical signal detector, also can be other transmitter, the corresponding described sender unit 4 of described signal receiving device 5 is located at the both sides in described region to be measured, concrete with reference to Fig. 3, the light that described sender unit 4 sends is through lens 7a, through described reaction cup 1, again through lens 7b, received by described signal receiving device 5, also namely described reaction cup 1 is region to be measured through described sender unit 4 with the zone line of described signal receiving device 5, described signal receiving device 5 transfers to described processor 6 after receiving the light signal of described signal generation apparatus transmitting, described processor 6 is the central controller of the device 100 of the debug measurement position of described reaction cup, control the running of the device 100 of the debug measurement position of described reaction cup, the speed of running is adjustable.
Described processor 6, for determining the sidewall locations of described reaction cup 1 according to described light signal, determines the data collection zone of described reaction cup 1 according to the sidewall locations of described reaction cup 1.
Concrete, after described processor 6 receives described light signal, determine the position of the sidewall of described reaction cup 1, the data collection zone of described reaction cup 1 can be determined according to the sidewall locations of the described reaction cup 1 determined.So, the position of the described data collection zone determined according to described sidewall locations according to described processor 6 can be more accurate, can not affect the selection of data collection zone because each reaction cup 1 there is geometric error, and then can not produce cumulative errors, measurement result is more accurate.
In the present embodiment, described processor 6 comprises computing module 61 and judge module 62.
Described computing module 61, for calculating the changing value of intensity level in setting cycle of described light signal.
Concrete, after described optical signal launch, after the wall of cup of described reaction cup 1, contrast the signal intensity before without reaction cup 1 wall of cup have a changing value, be specially a pad value, described setting cycle is specially signal and is transmitted into the interval value (being that calculating accurate also can be multiple interval value certainly) that Signal reception arrives signal transmitting and Signal reception again, calculates the changing value of the signal strength values in setting cycle.
Described judge module 62, for described changing value and setting value being compared, when described changing value is greater than described setting value, judges that described light signal passes the sidewall locations of position as described reaction cup 1 of described reaction cup 1.
Concrete, described light signal is not when touching the wall of cup of described reaction cup 1, a setting value is had in setting cycle, described setting value is the normal fluctuation value of described light signal, the value of the two is compared, when described changing value is greater than described setting value, namely judge the wall of cup of described light signal through described reaction cup 1, and position is herein the position of described reaction cup 1 wall of cup.
In the present embodiment, described processor 6 also comprises acquisition module 63 and metering module 64.
Described acquisition module 63, for obtaining the distance between the data collection zone of described reaction cup 1 and the sidewall of described reaction cup 1.Namely described data collection zone is the region of image data, and it should be noted that the described distance between the sidewall of described reaction cup 1 and described data collection zone is definite value, this definite value is given value.
Described metering module 64, for determining the data collection zone of described reaction cup 1 according to the sidewall locations of the corresponding reaction cup of described Distance geometry 1.Namely the wall of cup of described reaction cup 1 moves the length of described definite value again, and be described data collection zone, should be understood that, the movement velocity of described reaction cup 1 is adjustable.
In the present embodiment, described data collection zone is the central area of described reaction cup 1.
Concrete, described reaction cup 1 is generally cylindrical, certainly also comprises other shapes.The concentration of the reactant at the middle part of described reaction cup 1 is the optimum measuring point of described reaction cup 1, and thus described data collection zone is the central area of described reaction cup 1.Namely the described distance between the sidewall of described reaction cup 1 and middle part is definite value, and the wall of cup being described reaction cup 1 moves the length of described definite value again, and the central area namely moving to described reaction cup 1 is described data collection zone.
In the present embodiment, described sender unit 44 is also for launching described pulse signal;
Concrete, when reaction cup 1 moves to region to be measured, described signal receiving device 5 receives the light signal launched from sender unit 4, and by while described optical signal transmission to processor 6, described sender unit 4 goes back transponder pulse signal, described pulse signal is mainly used in gathering the response data in reaction cup 1, and described pulse signal is continuous signal.
Described signal receiving device 5 also for receiving described pulse signal, and by described pulse signal transmission to described processor 6.
Concrete, when reaction cup 1 moves to region to be measured, signal receiving device 5 receives the pulse signal launched from sender unit 4, and by described pulse signal transmission to described processor 6, described processor 6 can store described signal pulse.
Described processor 6 also comprises data processing module 65, and described processor 6, according to described data collection zone and described pulse signal, obtains the compositional data of the determinand in described reaction cup 1.
Concrete, determine the data collection zone of described reaction cup 1 according to the sidewall locations of described reaction cup 1 after, described processor 6, according to described data collection zone and described pulse signal, obtains the compositional data of the determinand in described reaction cup 1.Also namely according to the pulse signal in described data collection zone, the compositional data of the determinand in analytical reactions cup 1 is carried out.
The present invention also provides a kind of method of debug measurement position of reaction cup, and concrete reference Fig. 6 to Fig. 9, Fig. 6 are the schematic flow sheet of an embodiment of the debug measurement position of a kind of reaction cup of the present invention; Fig. 7 is the refinement schematic flow sheet of an embodiment of step S20 in Fig. 6; Fig. 8 is the schematic flow sheet of the acquisition data collection zone in Fig. 6; Fig. 9 is the schematic flow sheet obtaining determinand composition.
The method of the debug measurement position of described reaction cup comprises:
Step S10, when reaction cup 1 moves to region to be measured, described signal receiving device 5 receives the light signal launched from sender unit 4, and by described optical signal transmission to processor 6;
Concrete, the mode that described reaction cup 1 moves to described region to be measured can be rotation, namely reaction cup 1 is arranged on described code-wheel 2 (described code-wheel 2 is mainly used in the kind of the internal solution distinguishing described reaction cup 1, a described code-wheel 2 there is the described reaction cup 1 of multiple built-in same solution, , each described code-wheel 2 be provided with accommodating described reaction cup 1 holder 2a on) on, described region to be measured is turned to by described rotating disk 3, this advantage adds survey for circulating, one crawler belt can certainly be set, reaction cup 1 is via crawler-tread extremely region to be measured, two kinds of embodiments of the present invention are only both this, other described reaction cup 1 is sent to the mode in region to be measured all in protection scope of the present invention.Described sender unit 4 can be optical signal detector, also can be other transmitter, the corresponding described sender unit 4 of described signal receiving device 5 is located at the both sides in described region to be measured, concrete with reference to Fig. 3, the light that described sender unit 4 sends is through lens 7a, through described reaction cup 1, again through lens 7b, received by described signal receiving device 5, also namely described reaction cup 1 is region to be measured through described sender unit 4 with the zone line of described signal receiving device 5, described signal receiving device 5 transfers to described processor 6 after receiving the light signal of described signal generation apparatus transmitting, described processor 6 is the central controller of the device 100 of the debug measurement position of described reaction cup, control the running of the device 100 of the debug measurement position of described reaction cup, the speed of running is adjustable.
Step S20, described processor 6 determines the sidewall locations of described reaction cup 1 according to described light signal;
Concrete, after described processor 6 receives described light signal, determine the position of the sidewall of described reaction cup 1.
Step S30, described processor 6 determines the data collection zone of described reaction cup 1 according to the sidewall locations of described reaction cup 1;
Concrete, the data collection zone of described reaction cup 1 is determined according to the sidewall locations of the described reaction cup 1 determined.So, the position of the described data collection zone determined according to described sidewall locations according to described processor 6 can be more accurate, can not affect the selection of data collection zone because each reaction cup 1 there is geometric error, and then can not produce cumulative errors, measurement result is more accurate.
In the present embodiment, concrete with reference to Fig. 6, described processor 6 determines that according to described light signal the step S20 of the sidewall locations of described reaction cup 1 comprises:
Step S21, calculates the changing value of intensity level in setting cycle of described light signal.
Concrete, after described optical signal launch, after the wall of cup of described reaction cup 1, contrast the signal intensity before without reaction cup 1 wall of cup have a changing value, be specially a pad value, described setting cycle is specially signal and is transmitted into the interval value (being that calculating accurate also can be multiple interval value certainly) that Signal reception arrives signal transmitting and Signal reception again, calculates the changing value of the signal strength values in setting cycle.
Step S22, compares described changing value and setting value;
Described light signal, when not touching the wall of cup of described reaction cup 1, has a setting value in setting cycle, and described setting value is the normal fluctuation value of described light signal, the value of the two is compared.
Step S23, when described changing value is greater than described setting value, judges that described light signal passes the sidewall locations of position as described reaction cup 1 of described reaction cup 1.
Concrete, when described changing value is greater than described setting value, namely judge the wall of cup of described light signal through described reaction cup 1, and position is herein the position of described reaction cup 1 wall of cup.
In the present embodiment, when reaction cup 1 moves to region to be measured, signal receiving device 5 receive from sender unit 4 launch light signal, and by described optical signal transmission to processor 6 step S10 before also comprise:
Step S01, obtains the distance between the data collection zone of described reaction cup 1 and the sidewall of described reaction cup 1, and by described Distance Transmission to described processor 6;
Concrete, described data collection zone is the region of image data, and it should be noted that the described distance between the sidewall of described reaction cup 1 and described data collection zone is definite value, this definite value is given value.
Determine that according to the sidewall locations of described reaction cup 1 the step S30 of the data collection zone of described reaction cup 1 comprises:
Step S31, described processor 6 determines the data collection zone of described reaction cup 1 according to the sidewall locations of the corresponding reaction cup of described Distance geometry 1.
Concrete, the wall of cup of described reaction cup 1 moves the length of described definite value again, and be described data collection zone, should be understood that, the movement velocity of described reaction cup 1 is adjustable.
In the present embodiment, described data collection zone is the central area of described reaction cup 1.
Concrete, described reaction cup 1 is generally cylindrical, certainly also comprises other shapes.The concentration of the reactant at the middle part of described reaction cup 1 is the optimum measuring point of described reaction cup 1, and thus described data collection zone is the central area of described reaction cup 1.Namely the described distance between the sidewall of described reaction cup 1 and middle part is definite value, and the wall of cup being described reaction cup 1 moves the length of described definite value again, and the central area namely moving to described reaction cup 1 is described data collection zone.
In the present embodiment, when reaction cup 1 moves to region to be measured, signal receiving device 5 receive from sender unit 4 launch light signal, and by described optical signal transmission to processor 6 step S10 while, also comprise:
Step S11, when reaction cup 1 moves to region to be measured, signal receiving device 5 receives the pulse signal launched from sender unit 4, and by described pulse signal transmission to described processor 6;
Concrete, when reaction cup 1 moves to region to be measured, described signal receiving device 5 receives the light signal launched from sender unit 4, and by while described optical signal transmission to processor 6, described sender unit 4 goes back transponder pulse signal, described pulse signal is mainly used in gathering the response data in reaction cup 1, and described pulse signal is continuous signal.When reaction cup 1 moves to region to be measured, signal receiving device 5 receives the pulse signal launched from sender unit 4, and by described pulse signal transmission to described processor 6, described processor 6 can store all described signal pulses.
Determine the step S31 of the data collection zone of described reaction cup 1 according to the sidewall locations of described reaction cup 1, comprise afterwards:
Step S32, described processor 6, according to described data collection zone and described pulse signal, obtains the compositional data of the determinand in described reaction cup 1.
Concrete, determine the data collection zone of described reaction cup 1 according to the sidewall locations of described reaction cup 1 after, described processor 6 is according to described data collection zone and described pulse signal, obtain the compositional data of the determinand in described reaction cup 1, also namely according to the pulse signal in described data collection zone, the compositional data of the determinand in analytical reactions cup 1 is carried out.
In sum, the present invention determines the sidewall locations of described reaction cup 1 by described light signal, the data collection zone of described reaction cup 1 is determined again according to described sidewall locations, so, the position of the described data collection zone determined according to described sidewall locations is more accurate, can not affect the selection of data collection zone because each reaction cup 1 there is geometric error, and then can not produce cumulative errors, measurement result is more accurate.
These are only the preferred embodiments of the present invention; not thereby the scope of the claims of the present invention is limited; every utilize instructions of the present invention and accompanying drawing content to do equivalent structure or equivalent flow process conversion; or be directly or indirectly used in other relevant technical fields, be all in like manner included in scope of patent protection of the present invention.
Claims (10)
1. a method for the debug measurement position of reaction cup, is characterized in that, the method for the debug measurement position of described reaction cup comprises the following steps:
When reaction cup moves to region to be measured, signal receiving device receives the light signal launched from sender unit, and by described optical signal transmission to processor;
Described processor determines the sidewall locations of described reaction cup according to described light signal;
Described processor determines the data collection zone of described reaction cup according to the sidewall locations of described reaction cup.
2. the method for the debug measurement position of reaction cup as claimed in claim 1, it is characterized in that, described processor determines that according to described light signal the step of the sidewall locations of described reaction cup comprises:
Calculate the changing value of intensity level in setting cycle of described light signal;
Described changing value and setting value are compared;
When described changing value is greater than described setting value, judge that described light signal passes the sidewall locations of position as described reaction cup of described reaction cup.
3. the method for the debug measurement position of reaction cup as claimed in claim 1, it is characterized in that, when reaction cup moves to region to be measured, signal receiving device receive from sender unit launch light signal, and by described optical signal transmission to processor step before also comprise:
Obtain the distance between the data collection zone of described reaction cup and the sidewall of described reaction cup, and by described Distance Transmission to described processor;
Determine that according to the sidewall locations of described reaction cup the step of the data collection zone of described reaction cup comprises:
Described processor determines the data collection zone of described reaction cup according to the sidewall locations of the corresponding reaction cup of described Distance geometry.
4. the method for the debug measurement position of reaction cup as claimed in claim 1, it is characterized in that, described data collection zone is the central area of described reaction cup.
5. the method for the debug measurement position of reaction cup as claimed in claim 1, it is characterized in that, when reaction cup moves to region to be measured, signal receiving device receives the light signal launched from sender unit, and by described optical signal transmission to processor step while, also comprise:
When reaction cup moves to region to be measured, signal receiving device receives the pulse signal launched from sender unit, and by described pulse signal transmission to described processor;
Comprise determine the step of the data collection zone of described reaction cup according to the sidewall locations of described reaction cup after:
Described processor, according to described data collection zone and described pulse signal, obtains the compositional data of the determinand in described reaction cup.
6. a device for the debug measurement position of reaction cup, is characterized in that, the debug measurement location means of described reaction cup comprises reaction cup, code-wheel, rotating disk, sender unit, signal receiving device, processor:
Described reaction cup is placed on described code-wheel, and described code-wheel is fixed on described rotating disk;
Described emitter and described receiving trap split the both sides with described region to be measured, described sender unit is used for utilizing emitted light signal, described signal receiving device receives the light signal launched from sender unit, and by described optical signal transmission to described processor;
Described processor is used for the sidewall locations determining described reaction cup according to described light signal, and the sidewall locations of described reaction cup determines the data collection zone of described reaction cup.
7. the device of the debug measurement position of reaction cup as claimed in claim 6, it is characterized in that, described processor comprises computing module and judge module:
Described computing module, for calculating the changing value of intensity level in setting cycle of described light signal;
Described judge module, for described changing value and setting value being compared, when described changing value is greater than described setting value, judges that described light signal passes the sidewall locations of position as described reaction cup of described reaction cup.
8. the device of the debug measurement position of reaction cup as claimed in claim 6, it is characterized in that, described processor also comprises acquisition module and metering module:
Described acquisition module, for obtaining the distance between the data collection zone of described reaction cup and the sidewall of described reaction cup;
Described metering module, for determining the data collection zone of described reaction cup according to the sidewall locations of the corresponding reaction cup of described Distance geometry.
9. the device of the debug measurement position of reaction cup as claimed in claim 6, it is characterized in that, described data collection zone is the central area of described reaction cup.
10. the device of the debug measurement position of the reaction cup as described in any one of claim 6, is characterized in that, described sender unit is also for launching described pulse signal;
Described signal receiving device also for receiving described pulse signal, and by described pulse signal transmission to described processor;
Described processor also comprises data processing module;
Described data processing module, for according to described data collection zone and described pulse signal, obtains the compositional data of the determinand in described reaction cup.
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CN110596046A (en) * | 2018-06-12 | 2019-12-20 | 深圳市理邦精密仪器股份有限公司 | Reaction cup detection method and device based on laser scattering assembly and storage medium |
CN113125786A (en) * | 2021-04-28 | 2021-07-16 | 深圳市卓润生物科技有限公司 | Reaction cup state detection method and system |
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