DE10140527A1 - Multi-parameter display, for electro-chemical measuring and analysis instrument, has display presenting current value or condition, with linear indicator for each parameter - Google Patents

Abstract

An electrochemical instrument has a display (20) presenting a current value or condition, with a linear indicator (21) for each parameter. Each parameter (S, N, B, G, E, K, M) is preferably allocated a display linear radial vector (21.1-21.7), all vectors originating at a common starting point (22) Each vector line subtends the same angle to adjacent vectors on both sides. The current value of each parameter is represented by a point indicator on the line. The display field (20) between the indicator lines (23.1-23.7) has link lines (24.1-24.7) between indicator vectors (21.1-21.7).

Description

The invention relates to a display device for electrochemical measuring and analyzers, such as pH or conductivity meters, with one Display field, the current or saved device and / or measurement parameters reproduces. There is also one for each of these parameters on the display panel analog linear display provided. Such display devices are widely known in the field of measuring devices. So there are typical analog linear displays, for example, from straight rows of LEDs or a corresponding liquid crystal display on which optically perceptible points or bars the respective parameter in visualize its value.

In addition to analog displays, there are digital displays of the values corresponding parameters are common and should only be used in connection with the Background of the present invention can be addressed.

The latter lies in the problem that, for example electrochemical measuring and analysis devices in the industrial environment, which are used for Monitoring complex processes can be used in a variety of ways Parameters to be monitored. This is the condition of the pH measuring chain for the pH measurement is of crucial importance and can be independent parameters, such as. B. calibration data, response time etc. describe. Only if all parameters are sufficiently good values proper pH measurement is ensured.

Especially in the industrial environment, where there may not be a highly qualified one Process monitoring personnel, it is special important that display devices are very clear and eye-catching possible states of the system or of the deviating from the target conditions Visualize the measurement and analysis components used in it. This is not displayed with, for example, a series of bar displays, let alone with digital displays that only show numbers reached.

In this respect, the invention is based on the object Display device of the type mentioned in such a way that a large number of parameters "at a glance" detectable and abnormal parameters be visualized conspicuously.

This object is achieved by the in the characterizing part of claim 1 specified features solved. Accordingly, the display device is one so-called "network diagram" modeled, as it is in statistical form is known from statistical evaluations and presentations. So will display each parameter displayed on the display device Display vector assigned in the form of a linear display, with all Display vectors starting from at least one common starting point in different radial directions run on the display panel. The the respective parameter value is indicated by a corresponding pointer on the assigned display vector. In this context is on it to point out that the term "linear display" means that the pointer moves on a straight line, so it is one one-dimensional display. The relationship between the location of the Pointer on the linear display and the parameter value represented by it doesn't need to be a linear relationship in a mathematical sense, as well is clear from the table attached to the description.

Due to the essentially radial arrangement of the Display vectors creates a compact display field for a variety of parameters, that is clear and therefore particularly easy to grasp.

The quality and comprehensibility of the visualization is different Measures as specified in the subclaims still improved. So the display gains clarity when the Display vectors from a single central starting point and in uniform angular distances are arranged distributed over the display panel.

Through the preferred use of a point pointer on the individual Display vectors and their connection between two neighboring display vectors, a display mode is selected in which "Outliers" of the parameter values are particularly striking. Are the Display vectors standardized in their display scale so that all Pointer approximately the same distance to the target values have a central starting point, the resulting figure is almost a regular, closed polygon. A value deviates from its setpoint the corresponding pointer moves far inwards so that the polygon traceable at a glance, at least one dent inwards, if it does not have a sharp, inward-looking jag.

Other features, details, and advantages are as follows Description can be seen in which an embodiment based on the attached drawings is explained in more detail. Show it:

Fig. 1 is a block diagram of an electrometric pH meter in the measurement state with a display device according to the invention, and

Fig. 2 is a schematic view of the display device.

The overall arrangement shown in FIG. 1 is divided into the actual pH measuring device 1 and a process 2 monitored by it. The pH measuring device 1 is connected to a glass electrode 3 and a reference electrode 4 as measuring electrodes assigned to the process 2 . A Pt1000 resistor 6 is also connected. The measuring electrodes 3 , 4 and the Pt1000 resistor 6 are immersed in a solution 7 in a container 8 , the pH of which is to be measured.

As a voltage measuring device, the pH measuring device 1 contains an amplifier 9 acting as an impedance converter, a changeover switch 10 , an analog / digital converter 11 , a central unit 12 , a current source 13 for the Pt1000 resistor 6 , a ROM memory 14 , and one for data backup battery-operated RAM memory 15 and a digital display unit 16 . The ROM program 14 stores the control program (ZE program) for the central processing unit 12, which is designed as a microprocessor, and tables for three calibration solutions I, II and III, the pH values of which are available as a function of temperature, pH _I , pH _II and pH _III . Furthermore, limit pH values are pH _G1 . , , Ph _{G4 is} stored in the ROM memory 14 in order to be able to carry out the automatic calibration process in the pH measuring device 1 described in DE 29 37 227 C2. The calibration process described there need not be described again here.

In this automatic calibration process, pH values pH _1T1 and pH _{2T2 of} the two calibration _{solutions are} determined. These two values are stored in RAM 15 . If a measurement solution 7 is subsequently examined with the electrodes 3 , 4 , the central unit 12 receives voltage measurement values and temperature values from the measurement solution 7 via the analog / digital converter 11 and determines pH and zero values from these and the characteristic values stored in the RAM memory. Passage N and slope S of the measuring electrode characteristic curve are a temperature-standardized measuring voltage U _RT and from this the associated display value pH (U _RT ), which is displayed in the digital display unit 16 .

As is explicitly explained in DE 195 36 315 C2 of the applicant in connection with the measurement method discussed above, the display value pH (U _RT ) is compared with the pH values pH _1T1 and pH _{2T2 in} the comparator 17 used in the previous automatic calibration Calibration solution compared and the amount of pH difference deltapH ₁ and deltapH _{2 of} the displayed value pH (U _RT ) from the pH values pH _1T1 and pH _2T2 determined. In the discriminator 18 it is then determined whether deltapH ₁ and deltapH _{2 are} greater than a predetermined limit deltapH _limit . In other words, the so-called “measurement shelf N” is determined here, which still plays a role in the subsequent discussion of the actual display device 19 of the pH measuring device 1 .

A display device 19 according to the invention now has a display panel which is designed as a high-resolution LCD matrix display panel 20 . In the example shown, seven calibration and measuring parameters of the pH measuring device 1 are shown, namely the slope S and the zero crossing N of the measuring electrodes 3 , 4 , the impedance B of the reference electrode 4 , the impedance G of the glass electrode 3 , the so-called response time E of the measuring electrodes 3 , 4 , the calibration timer K and the measuring shelf M already mentioned above. Each of these parameters is assigned a display vector 21.1 to 21.7 designed as an analog linear display, which run in different radial directions on the display panel 20 starting from a common central starting point 22 , The respective value or state of the parameters S, N, B, G, E, K and M is represented by a corresponding pointer 23.1 to 23.7 on the assigned display vector 21.1 to 21.7 . As is clear from FIG. 2, the display vectors 21.1 to 21.7 are arranged at uniform angular intervals a over the display field 20 . Furthermore, the pointers 23.1 to 23.7 are designed as point pointers, that is to say that on the individual display vectors 21.1 to 21.7 the value or state of the parameter is represented only by a point - and not, for example, by a bar from the central starting point 22 . Between these point pointers 23.1 to 23.7 , connecting straight lines 24.1 to 24.7 are shown on the display field 20 between two adjacent display vectors 21.1 and 21.2 , 21.2 and 21.3 , etc., so that a more or less regular polyline results for the display of the overall parameter, as is the case here is indicated in Fig. 2.

The display vectors are normalized 21.1 to 21.7 in its display scale such that the pointers are 1.23 to 7.23 for permissible parameter values or states in a vector field v, on a rapid detection of parametric states of the display vectors r 21.1 are to 21.7 between the half and the entire radial length , In order to emphasize this visually, 50% dimension lines f and 100% dimension lines h circulate in the direction of rotation of the display 20 between the display vectors 21.1 to 21.7 as cross-connection lines.

An example of the standardization of the scales on the display vectors 21.1 to 21.7 can be found in the table following the present description, in which the pointer values 100%, 50% and 0% are compared to corresponding parameter values. It is pointed out that the selected parameter values are only examples and, depending on the measuring devices, electrodes and processes to be monitored, can deviate more or less significantly from these values.

In order to understand the table, some examples should be selected below. In connection with the slope S, the measuring electrodes have a standard slope of approx. 60 mV / pH. If it has turned out during calibration of the measuring electrodes 3 , 4 that this value has been reached, the corresponding display value is 100%. If the slope is lower, less than 100% is displayed - according to the table, the value 50% if the slope is 5.5 mV / pH below the normal slope.

With regard to the zero point N, the 0% and 50% values can be displayed if the zero point is ± 2 pH or ± 1 pH compared to the target Zero point are shifted.

The impedances of the reference and glass electrodes B and G are with 100%, i.e. optimally displayed if they correspond to the target values. 0% and 50% are displayed when the impedance value is like a fraction z. B. Rcal / 4 and Rcal / 2 or a multiple - namely 3 Rcal or 6 Rcal - or has a high value such as 100 kΩ and 200 kΩ.

Another calibration variable of the measuring electrodes is their response time, the for example at a value of <36 sec is optimal so that 100% are displayed.

According to the table, the display vector 21.6 for the calibration timer K can be standardized so that the 100% value is displayed when the calibration has just been completed, the 50% value with a remaining time of 20% of the calibration interval and 0% when the calibration timer has expired. The latter case is shown in Fig. 2 by the thick dashed course of the connecting straight lines 24.5 , 24.6 . It also becomes very obvious that in this case, where an immediate calibration is necessary, the display image of the display device 19 is extremely asymmetrical. The operating personnel are striking that something is wrong with the process or the measurement and that an action is necessary.

Finally, it should be explained in connection with the measurement shelf that the 100% value for M is displayed if the measured value pH is within the calibration range of e.g. B. pH = 4 and pH = 7 moves. If the measured value lies outside these limits, the value 50% is displayed for a deviation of, for example, ± 5 pH to the upper or lower limit, and the value 0% for a deviation of ± 10 pH. steepness

zero

reference impedance

glass impedance

Response time

Calibration

Measuring shelf (pH)

Claims (9)

1. Display device for electrochemical measuring and analysis devices, such as pH or conductivity meters, comprising
a current or saved device and / or measurement parameter displaying display field ( 20 ), and
an analog linear display ( 21 ) for each parameter (S, N, B, G, E, K, M) on the display panel ( 20 ),
marked by
a display vector ( 21.1-21.7 ) associated with each displayed parameter (S, N, B, G, E, K, M) as a linear display, with all display vectors ( 21.1-21.7 ) starting from at least one common starting point ( 22 ) in different radial directions run on the display field ( 20 ) and the respective parameter value (S, N, B, G, E, K, M) is represented by a pointer ( 23.1-23.7 ) on the assigned display vector ( 21.1-21.7 ). 2. Display device according to claim 1, characterized in that the display vectors ( 21.1-21.7 ) start from a single common, central starting point ( 22 ). 3. Display device according to claim 1 or 2, characterized in that the display vectors ( 21.1-21.7 ) are arranged at uniform angular intervals (a) distributed over the display panel ( 20 ). 4. Display device according to claim 1, 2 or 3, characterized in that the values of the parameters (S, N, B, G, E, K, M) are represented by a point pointer on the individual display vectors ( 21.1-21.7 ). 5. Display device according to one of claims 1 to 4, characterized in that on the display field ( 20 ) between the pointers ( 23.1-23.7 ) each two adjacent display vectors ( 21.1-21.7 ) a connecting line ( 24.1-24.7 ) is displayed. 6. Display device according to one of claims 1 to 5, characterized in that at least one tel of the display vectors ( 21.1-21.7 ) are standardized in their display scale such that the respective optimal value of the assigned parameter (S, N, B, G, E, K, M) is represented by a pointer position at the radially outer end of the display vector. 7. Display device according to one of claims 1 to 6, characterized in that at least some of the display vectors ( 21.1-21.7 ) are standardized in their display scale such that the pointers ( 23.1-23.7 ) allowable parameter values in a vector range (v) between the half and total radial length of the display vector ( 21.1-21.7 ). 8. Display device according to one of claims 1 to 7, characterized in that the display vectors ( 21.1-21.7 ) have standardized scales, with equivalent scale points each of two adjacent display vectors ( 21.1-21.7 ) being connected by cross-connecting lines (f, h). 9. Display device according to one of claims 1 to 8 for a pH measuring device, characterized in that the parameters (S, N, B, G, E, K, M) of the display vectors ( 21.1-21.7 ) are selected from calibration variables , such as the slope (S), the zero crossing (N), the impedance (B, G) and response time (E) of the pH measurement electrodes ( 3 , 4 ) and / or from current measurement parameters (M), such as actual measurement values and elapsed measurement time and calibration intervals (K).