JPH0259411B2 - - Google Patents

Description

[Detailed description of the invention] The present invention relates to electronic scales.

Generally, when using an electronic scale to add samples multiple times and measure their cumulative weight, one sample is placed on the receiving tray, then the next sample is not placed on the tray immediately after a certain period of time has elapsed. When trying to load the next sample, the indicated value may fluctuate due to electronic scale drift. Conventional electronic scales have a problem in that the correct cumulative weight cannot be obtained unless the amount of variation is reduced after reading the cumulative weight. In general, load cells, which are the load-to-electrical conversion mechanism of electronic scales, have a phenomenon (creep) in which the amount of strain caused by external force changes over time due to the characteristics of the material, which is also a cause of the above-mentioned drift. Therefore, if hardware measures such as special modifications to the strain gauge of the load cell are used to solve this problem, this will result in a significant increase in costs.

The present invention has been made in view of the above, and it is an object of the present invention to provide an electronic scale that can automatically detect when a sample is added, automatically correct for the above-mentioned drift, and display the correct cumulative weight. purpose.

The electronic scale of the present invention samples the measurement data from the load detection section every moment, and for each sampling, the average value of the latest predetermined number of pieces of data is obtained.
W ₀ is calculated, and the difference δ ₀ between the average value W ₀ and the average value W ₁ of i items immediately before it is calculated, and the difference δ ₀ is constantly compared with the immediately previous difference δ ₁ , and the difference δ If ₀ decreases a predetermined number of times in a row, it is determined that the measured value is transitioning to a stable state, and the number of data is increased each time data is sampled to separately calculate the average value W _{0 ′} . When the difference δ 0 becomes 0, it is determined that the measured value has become completely stable, and the average value W ₀ ′ at that time is memorized, and if the difference δ ₀ increases a predetermined number of times (q times), the measured value is in a changing state. Migrated (sample added to saucer)
The average value just before reaching the specified number of times.
Subtract the above-mentioned stored average value W ₀ ′ from Wq′,
The present invention is characterized in that the drift is corrected by adding the value ΔW ₀ ' to the tare amount value T stored in the tare amount memory.

Embodiments of the present invention will be described below based on the drawings.

FIG. 1 is a block diagram showing the configuration of an embodiment of the present invention.

The load measuring section 1 converts the data of the load W on the tray into digital data moment by moment at minute intervals, for example, 0.1 seconds, and outputs the data to the control section 2. The random access memory 21 in the control unit 2 is provided with an area for storing up to m pieces of the above-mentioned data, and the oldest data is discarded every time the latest sampling data d ₀ arrives, so d ₀ is always stored. , d ₁ ...d _n-1 data is stored. In addition to the data storage area, the random access memory 21 has areas for storing various calculation results, which will be described later, and areas for various registers. A processing program, which will be described later, is written in the read-on memory 22 of the control unit 2, and the central processing unit 23 executes this program. Further, the control unit 2 is provided with a tare amount memory 24 for storing the tare amount, and an average value memory 25 for storing the average value at the time of complete stability, which will be described later. In addition to the load measuring section 1, the control section 2 is connected to a switch for operating an electronic scale, a numeric keypad 3 for inputting various constants, etc., and a display 4 for displaying calculation results.

Next, we will discuss the effect. FIG. 2 is a flowchart showing a processing program according to an embodiment of the present invention. When the sampling data from the load measuring section 1 arrives, the previous m pieces of data are each shifted,
The latest data d ₀ is imported (ST1,
ST2). Next, the average value W ₀ is calculated using the latest i pieces of data (for example, 3 pieces), and the average value W ₀
Then, tare weight subtraction processing is performed using the tare amount T stored in advance in the tare amount memory 24 (ST3). The tared average value W ₀ is subtracted from the immediately preceding average value W ₁ to calculate the difference δ ₀ (ST4), and the difference δ ₀ and the immediately preceding difference δ ₁ are compared (ST5,
ST6). If δ ₀ < δ ₁ , register q is set to 0 and register p is counted up by 1 (ST7,
ST13). If δ ₀ > δ ₁ , register p is set to 0 and register q is counted up by 1 (ST10,
ST12). These registers p and q are counted up until they reach a predetermined value (for example, 3) (ST8, ST11). Also, when δ ₀ = δ ₁ , if δ ₀ = 0, a routine similar to δ ₀ < δ ₁ is given, and if δ ₀ ≠ 0, a routine similar to δ ₀ > δ ₁ is given (ST9). . If the register p reaches a predetermined value in ST8, that is, if δ ₀ < δ ₁ < δ ₂ holds, it is determined that the measured value is transitioning to a stable state, and the number of data is sequentially increased at each sampling. to calculate the average value W ₀ ′, and tare weight subtraction processing is performed using the tare amount T in the tare amount memory 24 (ST14,
ST15, ST16). Note that the number of data is increased until it reaches the maximum number m of data collection. and ST17
If register k has not reached a predetermined value (for example, 3) and δ ₀ = 0, register k is counted up by 1 and tared W ₀ ' is displayed (ST18,
ST19, ST21), if δ ₀ ≠ 0, set register k to 0
and similarly display W ₀ ′ (ST20, ST21).
If register k has reached the predetermined value (3), that is, δ ₀ = δ ₁ = δ ₂ = 0, it is determined that the measured value is completely stable, and W ₀ ' is captured and stored. (ST22, ST23). If the flag W is not set, W ₀ ' is stored in W of the average value memory 25, and the flag W is set (ST23, ST25). If this flag W is set, the subsequent W ₀ ' will not be stored in W. Then, the process advances from ST24 or ST25 to ST·21, displays W ₀ ′, and returns to ST1. Next, in ST11, if register q has reached a predetermined value (3), that is, if δ ₀ > δ ₁ > δ ₂ holds true, it is determined that the measured value has transitioned to a fluctuating state, and at that time, the register q is If k has reached a predetermined value, △W is calculated by subtracting the average value memory W from the average value Wq′ just before δ ₀ > δ ₁ > δ ₂ holds, and the tare amount memory 2 is
This ΔW is added to the tare amount T of No. 4 and stored (ST26, ST27). Next, register k is reset to 0, flag W is reset, register n is set to 0, and W ₀ ' is displayed (ST28, ST29, ST30,
ST31). Note that if the register k has not reached the predetermined value in ST26, ST27, ST28, and ST29 are jumped and the process proceeds to ST30. Then return from ST31 to ST1.

The above flowchart will be explained with reference to the load-time characteristic diagram shown in FIG. When the sample A is placed on the tray of the load measuring section 1, the measured value rapidly increases and eventually begins to shift to a stable state at section a. At this time, the difference δ ₀ between the latest i average value W ₀ and the immediately preceding average value W ₁ decreases sequentially, but the register p
The average value W ₀ ' is calculated by gradually increasing the number of data and improving accuracy. Then, as more time passes, δ ₀ = 0 in part b, but it is determined by register k that this has continued a predetermined number of times, and it is determined that the state has entered a completely stable state, and the average value at that time is W ₀ ' is stored as W. Next, when sample A' is placed on the tray, the measured value at part c increases rapidly, but at this time, the above-mentioned difference δ ₀ increases more than the immediately preceding difference δ ₁ , and the tendency of increase continues for a predetermined number of times. Continuity is recognized by register q and transition to a fluctuating state is detected. Then, if △W is calculated by subtracting the above-mentioned W from the average value Wq' immediately before the increasing tendency continues for a predetermined number of times, that is, the average value Wq' immediately before the transition to the variable work state, This means that the amount of drift that occurred until the time has elapsed has been calculated, and if the amount of drift ΔW is added to the amount of tare weight T, the drift will be corrected during the tare weight subtraction process. By executing this every time a sample is placed, the cumulative weight will be the correct value.

Next, a main part of a modification of the flowchart shown in FIG. 2 is shown in FIG. The feature of this embodiment is that ST41 to ST45 are inserted between ST23 and ST24 in FIG. That is, by providing a register s,
After reading W ₀ ', if the register s has not reached a predetermined value (for example, 10), set the register s to 1.
Count up (ST41, ST42), and if the predetermined value has been reached, calculate △W by subtracting the s previous average value Ws' from the latest W ₀ ' of the average value data, and calculate △W.
Add W to the tare amount T in the tare amount memory 24 (ST43), reset the register s to 0, and reset the flag W (ST44, ST45).
Proceed to ST24. To explain this effect using the enlarged view of part V in FIG. 5, the register s is counted up every time _d0 data is sampled. If you set it to 0.1 seconds, the time from Ws' to _W0 ' will be 1 second, and △W will be calculated every second from placing sample A to placing sample A' in Figure 3. It is added to the tare amount T. That is, δ ₀ > δ ₁ > δ ₂
Drift correction is performed every second until a fluctuation state of
The process of ST27 is performed to correct the drift. In this way, even when the data is stable, the drift can be corrected and displayed every moment.
As shown in the figure, which is an explanatory diagram of correction of the creep characteristic of an electronic scale, correction can be made every moment when a creep phenomenon occurs.

In addition, when the load is 0, after δ ₀ = δ ₁ = δ ₂ = 0 is established, i+n reaches the maximum data collection number m and the average value of m data is calculated in ST16, and register k is set to a predetermined value. If the value is (3), it is the average value.
W ₀ '(0) is stored, and when s=10, ST43 is executed and 0 is always displayed.

Furthermore, since the flowchart of the present invention is not suitable for measuring changes in weight, it can be used by switching between the change measurement program and the change measurement program using the operation switch 3.

As explained above, according to the present invention, when a certain sample is placed on a receiving tray during sample preparation work, etc., and the amount of the sample is insufficient and the sample is brought in from another room and added, the sample is placed first. If the sample weight value changed due to drift, with conventional equipment it was necessary to subtract the amount of change later in order to correct and obtain the cumulative weight, but this is automatically corrected. Therefore, there is no need to remember the amount of change and calculate it later. If a register s is provided and the configuration is configured to constantly correct, the 0 point will always be corrected and displayed, so you can always press the tare key like in the conventional device to
There is no need to check the points. Furthermore, since the creep phenomenon can also be corrected, correct measured values can be obtained even if the power is turned on without sufficient warming up. It has no mechanism and is inexpensive. By making the correction period by the register s short, corrections are made every short period of time, and weighing values can always be obtained with reliable accuracy, thereby improving work efficiency.

[Brief explanation of drawings]

Fig. 1 is a block diagram showing the configuration of the embodiment of the present invention, Fig. 2 is a flowchart showing its processing program, Fig. 3 is an explanatory diagram of the operation of the embodiment of the invention shown in a load-time curve, and Fig. 4 is a diagram showing the operation of the embodiment of the present invention. A flowchart showing main parts of a processing program according to another embodiment of the present invention,
FIG. 5 is an explanatory diagram of the operation of another embodiment shown in the enlarged view of the V section in FIG. 3, and FIG. 6 is an explanatory diagram of the operation of another embodiment of the present invention in the case of correcting the creep phenomenon. 1... Load measuring section, 2... Control section, 3... Operation switch and numeric keypad, 4... Display, 21...
Random access memory, 22... Read-on memory, 23... Central processing unit, 24... Tare amount memory, 25... Average value memory.

Claims (1)

[Scope of Claims] 1. In an electronic scale equipped with a tare subtraction function that subtracts a value stored in a tare amount memory from a measured value, means for sampling and storing measurement data every moment, and a means for sampling and storing the latest predetermined data for each sampling. Means for calculating the average value W ₀ of number data and its average value
means for calculating the difference δ ₀ between W ₀ and the immediately preceding average value W ₁ ; means for comparing the difference δ ₀ with the immediately preceding difference δ ₁ to determine whether there has been an increase or decrease; means for calculating the average value W ₀ ' by sequentially increasing the number of data for each sampling when a predetermined number of consecutive samplings are performed; and means for calculating the average value W ₀ ' when the difference δ ₀ becomes 0 for a predetermined number of consecutive times; and means for storing the above-mentioned average value when the above-mentioned increase continues for a predetermined number of times.
An electronic scale comprising means for subtracting W ₀ ' from the average value Wq' immediately before the series, and adding and storing that value to the value stored in the tare amount memory. 2. If the above increase does not occur a predetermined number of times within a preset predetermined time, subtract the average value W ₀ ' at the time when the predetermined time has elapsed from the average value Ws' at the start of counting for the predetermined time, and use that value as the tare weight. 2. The electronic scale according to claim 1, further comprising means for adding and storing the value stored in the quantity memory.