JP2019207261A - electronic balance - Google Patents

Abstract

To provide an electronic balance capable of measuring a specific substance of a target collection weight in a sample containing the specific substance.SOLUTION: An electronic balance is configured to include: first input means 31a to which weight ratio information of a specific substance contained in a sample is input; second input means 31b to which a target collection weight WE of the specific substance contained in the sample is input; and calculation means 32 for calculating a target metering value WT of the sample required for collecting the specific substance of the target collection weight WE based on the weight ratio information and the target sampling weight WE.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an electronic balance.

1 mg / ml sodium tartrate (chemical formula: C4H4Na2O6, molecular weight: 1
94.08) in preparing an aqueous solution of sodium tartrate dihydrate (chemical formula: C4H4N
a2O6 · 2H2O, molecular weight: 230.08) may be used. Since this sodium tartrate dihydrate contains hydration water, the experimenter calculates the target measurement value of sodium tartrate dihydrate dissolved in 1 ml of water by the following formula (1), .Weigh 18 mg of sodium tartrate dihydrate with an electronic balance and weigh sodium tartrate dihydrate with an arbitrary measurement value α with an electronic balance to dissolve sodium tartrate dihydrate with an arbitrary measurement value α. Is calculated by the following formula (2) to measure 0.84 α ml of water (see, for example, Patent Document 1).
1 × 230.08 / 194.08 = “target measurement value 1.18” (1)
α × 194.08 / 230.08 = “target amount 0.84α” (2)

JP 2004-20884 A

However, when an experimenter calculates using the formulas (1) and (2), it takes time and labor, and a calculation error may occur.
In view of the above, an object of the present invention is to provide an electronic balance capable of weighing a specific object having a target collection weight in a sample containing the specific object.

  The electronic balance of the present invention made to solve the above problems is a storage means for storing two or more calculation methods different for each sample adjustment method, a state switching means for calling one calculation method from the storage means, A first input means for inputting the weight ratio information of the specific object contained in the sample, a second input means for inputting a target sampling weight of the specific object contained in the sample, and the switching means. A called calculation method, and a calculation means for calculating a target measurement value of a sample necessary for collecting a specific object of the target collection weight based on the weight ratio information and the target collection weight. ing.

  According to the electronic balance of the present invention, by inputting an adjustment method, weight ratio information, and a target sampling weight by an experimenter or the like, a target measurement value of a sample necessary for sampling a specific target sampling weight is calculated Is done. Thus, the experimenter or the like can collect a specific object having a target collection weight by measuring the sample having the calculated target measurement value.

  As described above, according to the electronic balance of the present invention, it is possible to reduce the labor involved in manual calculation, and to prevent measurement errors due to calculation errors.

(Means and effects for solving other problems)
In the invention described above, display means for displaying the measured value of the sample placed on the load detection unit and displaying the target measured value may be provided.

In the above invention, the display means may display a collected weight of a specific object placed on the load detection unit.
As a result, the target measurement value and the collected weight, which conventionally required two calculations, can be confirmed simultaneously on one screen, and measurement can be performed while recognizing it together with the measurement value, thereby improving work efficiency. At the same time, it is possible to prevent calculation errors due to manual calculation.

Further, in the above invention, a storage unit for printing or transferring the final measured value of the sample placed on the load detection unit and the final collected weight of the specific object, and the target measured value is provided. May be.
Thereby, the measurement result can be recorded without fail.

In the above invention, the sample is a hydrate, the specific substance is a substance obtained by removing water of hydration from the hydrate, and the weight percentage information includes the molecular weight of the hydrate, the hydration The molecular weight of water may be used.
In the above invention, the weight ratio information may be the molecular weight of the compound and the molecular weight of the salt of the previous compound.
Furthermore, in the above invention, the sample may be a mixture, the specific product may be one compound, and the weight ratio information may be a weight ratio of the one compound in the mixture.

The block diagram which shows an example of a structure of the electronic balance which concerns on this invention. The figure which shows an example of a display display screen. The figure which shows the example of printing of a measurement result.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The present invention is not limited to the embodiments described below, and it goes without saying that various aspects are included without departing from the spirit of the present invention.

FIG. 1 is a block diagram showing an example of the configuration of an electronic balance according to the present invention. The electronic balance 1
A load detector 10 having a weighing pan 10a, a signal processor 20, and a microcomputer 50
A display 60 on which an image is displayed, and operation keys 61 for an experimenter to perform an input operation.
And a printing unit 62. In addition, description of each part is mentioned later.
In addition, the electronic balance 1 according to the present invention is a compound other than the salt in the salt of the “adjustment 1: hydrate (PREPARATION-HYDRATE)” when measuring a compound other than hydrated water in the hydrate. Weighing “Adjustment 2: Salt (PREPARATION-CHLORINE)” and “Adjustment 3: Molecular weight (PREPARATION-MOLECULAR)”, weigh one compound in the mixture Can be used for “Adjustment 4: PREPARATION-PURITY”.

FIG. 2 is a diagram showing an example of a screen displayed on the display 60, and weighed the compound “sodium tartrate” having a “target sampling weight of 0.00100 g” using the hydrate “sodium tartrate dihydrate”. Shown the display screen when
In the first line of the screen, “Adjustment: Hydrate” indicating that “Adjustment 1: Hydrate” is executed is displayed.
In the second row, “target amount: 0.00118 g” indicating the target measurement value (TARGET) of sodium tartrate, which is a specific item to be collected, is displayed.
In the third row, “Measurement amount: 0.00098 g” indicating the measurement value (GROSS) of the hydrate placed on the weighing pan 10 a is displayed.
In the fourth line, the collected weight of sodium tartrate placed on the weighing pan 10a (PICKING
“Collected amount: 0.00083 g” is displayed.

Thereby, in the electronic balance 1 of the present invention, the experimenter is displayed on the display 60.
While confirming “target amount: 0.00118 g”, “measured amount: 0.00098 g” is “target amount: 0.00118 g” (or “collected amount: 0.00083 g” is “collected amount: 0.00100”.
g "), sodium tartrate dihydrate will be placed on the weighing pan 10a.

Here, the configuration of the electronic balance 1 according to the present invention will be described.
The load detection unit 10 detects the weight of a sample such as sodium tartrate dihydrate placed on the weighing pan 10a with a load cell (not shown), and analogs at a predetermined time interval Δt (for example, every several milliseconds). The signals are sequentially output to the signal processor 20.
The signal processor 20 amplifies the analog signal detected from the load detector 10.
a and an A / D converter 20 for converting the amplified analog signal into a digital signal (metric value) WG
b.

The microcomputer 50 includes a CPU 30 and a memory 40. CPU30
When the functions processed by are described as a block, “weight ratio information” and “target collected weight WE”
Are input and stored in the memory 40, a calculation unit 32 for calculating the “target measurement value WT”, a state switching unit 33 for selecting the type of “adjustment” to be executed, and a “target measurement value WT”.
And display means 34 for displaying “weighing value WG” and “collected weight WP” on display 60;
The storage unit 35 prints the “target weighing value WT”, “final weighing value WG ′”, and “final collected weight WP ′” by the printing unit 62.

The state switching means 33 receives an input signal for executing “adjustment 1: hydrate”, “adjustment 2: salt”, “adjustment 3: molecular weight” or “adjustment 4: purity” from the operation key 61. ,chosen"
Control to execute “adjustment”. That is, the experimenter calls “Adjustment 1: Hydrate”, “Adjustment 2: Salt”, “Adjustment 3: Molecular Weight”, and “Adjustment 4: Purity” by using the operation keys 61.

The input means 31 includes “weight ratio information (parameters a to e)” of the specific object contained in the sample necessary for executing the selected “adjustment” and “target sampling weight (parameter A) of the specific object.
) "Is displayed on the display 60, the" weight ratio information "input to the first input means 31a, and the" target sampling weight WE "input to the second input means 31b. Is stored in the memory 40.
For example, when “Adjustment 1: Hydrate” is selected as shown in FIG. 2, the experimenter uses the operation keys 61 to display the target sampling weight WE “0.00100 g (parameter A) on the parameter input screen. ”, Molecular weight of sodium tartrate dihydrate (W.MOLECULAR)“ 230.08 (parameter a) ”, and molecular weight of hydrated water contained in sodium tartrate dihydrate“ 18 × 2 (parameter b) ” ".

When “Adjustment 2: Salt” is selected, the experimenter uses the operation keys 61 to display “Target sampling weight WE (Parameter A)” and “Compound (W.MOLECULAR: Parameter) on the parameter input screen. a) "and" salt molecular weight (parameter c) "contained in the compound.
When “Adjustment 3: Molecular Weight” is selected, the experimenter uses the operation keys 61 to display “Target Collected Weight WE (Parameter A)” and “Molecular Weight of Compound (W.MOLECULA) on the parameter input screen.
R: Parameter a) ”and“ Molecular weight molecular weight (parameter d) ”contained in the compound
Enter.
When “Adjustment 4: Purity” is selected, the experimenter uses the operation keys 61 to display “Target sampling weight WE (parameter A)” on the parameter input screen and “1” of one compound in the mixture.
Enter “% by weight (parameter e)”.

Based on the “weight ratio information (parameters a to e)” and the “target collected weight WE (parameter A)”, the calculating means 32 “samples” necessary for collecting a specific object of the target collected weight WE.
Control for calculating the “target measured value WT” is performed.
For example, when “Adjustment 1: Hydrate” shown in FIG. 2 is selected, the following formula (1 ′) and “0.00100 g (parameter A)” and “230.08 ( Using “parameter a)” and “18 × 2 (parameter b)”, “target amount (target measured value) WT: 0
. "00118g" is calculated.
“Target sampling weight WE: 0.00100 g” × 230.08 / (230.08-18 × 2
) = “Target amount WT: 0.00118 g” (1 ′)

When “adjustment 2: salt” is selected, “target collection weight WE (parameter A)”, “molecular weight of the compound (parameter a)”, “ The “target amount WT” is calculated using the “molecular weight of the salt (parameter c)”.
Target sampling weight WE (parameter A) × molecular weight of compound salt (parameter a) / (molecular weight of compound (parameter a) −molecular weight of salt (parameter c)) = “target amount WT” (3)

Further, when “Adjustment 3: Molecular weight” is selected, “Target collection weight WE (parameter A)”, “Molecular weight of the compound (parameter a)”, “
The “target amount WT” is calculated using the “molecular weight of the mother nucleus molecular weight (parameter d)”.
Target sampling weight WE (parameter A) × compound molecular weight (parameter a) / molecular weight of parent molecular weight (parameter d) = “target amount WT” (4)

When “Adjustment 4: Purity” is selected, the following formula (5) and “target sampling weight WE (parameter A)” and “weight% (parameter e)” stored in the memory 40 are used. And
“Target amount WT” is calculated.
Target sampling weight WE (parameter A) × 100 / weight% (parameter e) = “target amount WT” (5)

The display means 34 displays the “measurement amount (measurement value) WG” of the sample placed on the weighing pan 10 a and the “collection amount (collection weight) WP” of the specific object on the display 60, and “target amount”. Control to display “WT” on the display 60 is performed. The “measured amount WG” may be a value obtained by previously taring the medicine-wrapping paper or tare on the weighing pan 10a.
For example, when “Adjustment 1: Hydrate” is selected, the screen shown in FIG.
In the first line of the screen, “Adjustment: Hydrate” selected by the state switching means 33 is displayed.
On the second line, “target amount: 0.001” is calculated for the target amount WT calculated by the calculating means 32.
18g "is displayed.
In the third row, the digital signal (measurement value) WG acquired by the signal processor 20 is “
“Measurement amount: 0.00098 g” is displayed.
In the fourth line, the following equation (1 ″), “230.08 (parameter a)”, “18 × 2 (parameter b)”, and digital signal (measurement value) WG stored in the memory 40 are stored. The collected amount WP calculated by using “collected amount: 0.00083 g” is displayed.
“Measurement amount WG: 0.00098 g” × (230.08−18 × 2) /230.08= “
Collected amount WP: 0.00083 g ”(1 ″)

When “Adjustment 2: Salt” is selected, “Adjustment: Salt” is displayed on the first line of the screen, and the following equation (3 ′) and memory are displayed on the fourth line of the screen. 40 “Molecular weight of the salt of the compound (parameter a)”, “Molecular weight of the salt (parameter c)” and “Digital signal (metric value)”
The “collected amount WP” calculated using “WG” is displayed.
Measured amount WG × (molecular weight of compound salt (parameter a) −molecular weight of salt (parameter c))
/ Molecular weight of compound salt (parameter a) = “sampled amount WP” (3 ′)

When “Adjustment 3: Molecular weight” is selected, “Adjustment: Molecular weight” is displayed on the first line of the screen, and the following equation (4 ′) and memory are displayed on the fourth line of the screen. The “collected amount WP” calculated using the “molecular weight of the compound (parameter a)”, the “molecular weight of the parent molecular weight (parameter d)” and the “digital signal (measured value) WG” stored in 40 is displayed. Will be.
Measured amount WG × Molecular weight molecular weight (parameter d) / compound molecular weight (parameter a)
= "Collected amount WP" (4 ')

When “Adjustment 4: Purity” is selected, “Adjustment: Purity” is displayed on the first line of the screen.
In the fourth line of the screen, the following formula (5 ′) and “weight% (
“Sampled amount WP” calculated using “parameter e)” and “digital signal (measured value) WG”
"Will be displayed.
Measurement amount WG × weight% (parameter e) / 100 = “collection amount WP” (5 ′)

When the experimenter or the like finishes the weighing operation, the storage unit 35 uses the operation key 61 to use the “final weighing value WG ′” of the sample placed on the weighing pan 10a and the “final collected weight WP ′” of the specific object. "When"
The printing unit 62 controls to print the “target measurement value WT”. FIG. 3 is a diagram illustrating an example of a sheet on which a measurement result is printed.
FIG. 3 (a) shows a “target sampling weight WE:
The results are shown when weighed “0.00100 g” of the compound “sodium tartrate”.
In the first line, “PREPARATION-HYDRATE” indicates that “Adjustment 1: Hydrate” has been executed.
Is printed.
In the second line, the sample name “C4H4Na2O6 · 2H2O” input with the operation key 61 is printed.
On the third line, “W.MOLECULAR: 230.08” indicating the parameter a is printed.
On the fourth line, “HYDRATE: 18 × 2” indicating the parameter b is printed.
In the fifth line, “TARGET: 0.00118 g” indicating the target measurement value WT of sodium tartrate dihydrate (sample) to be collected is printed.
In the sixth line, “GROSS: 0.00098 g” indicating the measurement value WG ′ of the sodium tartrate dihydrate placed on the weighing pan 10a is printed.
The seventh line indicates the collected weight WP ′ of sodium tartrate placed on the weighing pan 10a “
"PICKING: 0.00083g" is printed.

  3B shows the measurement result of “Adjustment 2: Salt (PREPARATION-CHLORINE)”, and FIG. 3C shows the measurement result of “Adjustment 3: Molecular weight (PREPARATION-MOLECULAR)”. (D) shows the measurement result of “Adjustment 4: Purity (PREPARATION-PURITY)”.

As described above, according to the electronic balance 1 of the present invention, the target weighing value WT and the collected weight WP, which conventionally required two calculations, can be confirmed simultaneously on one screen, and can be combined with the weighing value WG. It is possible to measure while recognizing it, improving work efficiency and preventing calculation errors due to manual calculation. Also, the obtained measurement results (WG ′, WP ′, WT) can be recorded without error.

  The present invention can be applied to an electronic balance.

DESCRIPTION OF SYMBOLS 1 Electronic balance 31 Input means 31a First input means 31b Second input means 32 Calculation means

Claims (7)

State switching means for selecting the type of adjustment to be performed on the sample;
Storage means for storing a calculation formula for calculating a target measurement value corresponding to the type of adjustment;
First input means for inputting the weight ratio information of the specific substance contained in the sample;
Second input means for inputting a target sampling weight of a specific substance contained in the sample;
Formula for the type of adjustment selected by the state switching means and said weight ratio information and is input to the first input means, based on the target sampling weight input to the second input means, said target An electronic balance comprising: a calculation means for calculating a target measurement value of a sample necessary for collecting a specific object having a collected weight. The electronic balance according to claim 1, further comprising a display unit that displays a measurement value of the sample placed on a load detection unit and displays the target measurement value. The electronic balance according to claim 2, wherein the display unit displays a collected weight of the specific object placed on the load detection unit. 4. The storage device according to claim 3, further comprising: a storage unit that prints or transfers the final measurement value of the sample placed on the load detection unit, the final collected weight of the specific object, and the target measurement value. The electronic balance described.   The sample is a hydrate, the specific substance is a substance obtained by removing hydrated water from the hydrate, and the weight percentage information includes the molecular weight of the hydrate and the molecular weight of the hydrated water. The electronic balance according to any one of claims 1 to 4, characterized in that:   5. The sample according to claim 1, wherein the sample is a salt of the compound, the specific substance is a salt, and the weight ratio information is a molecular weight of the compound and a molecular weight of the salt of the compound. An electronic balance according to claim 1. 5. The sample according to claim 1, wherein the sample is a mixture, the specific product is a single compound, and the weight ratio information is a weight ratio of the single compound in the mixture. The electronic balance according to item.