JPH028676B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a control rod position detection and reading device in a control rod position indicating system of a BWR nuclear power plant.

Generally, when operating a nuclear reactor, it is necessary to display each stop position of a large number of control rods arranged in the reactor and to measure the control rod operating time between the fully inserted and fully withdrawn positions.

For this reason, in the past, a plurality of position detection reed switches were arranged corresponding to each stop position of the control rod, and the signals obtained through these reed switches were encoded through a coding circuit. The on/off signals are extracted from the reed switches corresponding to all insertion positions and all withdrawal positions via a waveform shaping circuit, and the obtained coded signal is input to the display device to digitally display the control rod position. The control rod operating time between the fully inserted and fully withdrawn positions was adjusted by inputting on/off signals to the measuring device.

However, in the conventional method described above, many transistors, diodes, and other elements are required for the coding circuit, waveform shaping circuit, etc., making the circuit configuration complicated, and a large number of control rods are installed in the reactor. Therefore, if a coding circuit and a waveform shaping circuit were to be provided for each of these control rods, the number of elements used would be extremely large, resulting in a disadvantage that the entire device would be expensive.

The present invention eliminates the drawbacks of the above-mentioned prior art,
It is an object of the present invention to provide an extremely economical control rod position detection/reading device that has a small number of elements, has a simple circuit configuration, and is capable of displaying the control rod position and measuring the control rod operation time between the fully inserted and fully withdrawn positions. purpose.

In order to achieve this object, the present invention arranges a reed switch for detecting the control rod stop position at the intersection of the matrix circuit, and when the reed switch opens or closes, each control rod is detected through the row direction wiring and column direction wiring of the matrix circuit. In addition to taking out the logic signal representing the control rod position, on/off signals for measuring control rod operation time are taken out through the row direction wiring and column direction wiring to which the reed switches for all insertion positions and all withdrawal positions are connected. It is characterized by

Hereinafter, the present invention will be explained with reference to the drawings.

FIG. 1 shows a main part configuration diagram of a control rod position indicating system according to an embodiment of the present invention, in which 1 is a control rod position detection device, 2 is a control rod position reading device, and 3 is a control rod position It is a processing device.

The control rod position detection device 1 is arranged corresponding to each stop position of the control rod, as shown in FIG. 2a.
For example, 25 reed switches 1A and, although not directly related to the gist of the present invention, 24 reed switches arranged corresponding to the drift position and the position where the control rod cannot stop between each stop position. 1B. These reed switches 1A and 1B are arranged at equal intervals from the fully inserted position "00" to the fully withdrawn position "48", and in the figure, each stop position is "00".
Each drift position is represented by an odd number from "01" to "47". Further, each of these reed switches is connected to each matrix intersection formed by five row direction wirings P1 to P5 and six column direction wirings P6 to P11, as shown in FIG. 2b. . That is, the reed switches 1A corresponding to each stop position are connected to respective matrix intersections, while the reed switches 1B corresponding to the drift positions are connected all at once to one matrix intersection, as represented by ODD. ing.

As shown in FIG. 3, the control rod position reading device 2 includes a signal input conversion circuit 21, a control rod fully inserted and fully withdrawn position signal calculation circuit 22, a control rod fully inserted and fully withdrawn position signal drive circuit 23, and a drift signal. It is composed of an arithmetic circuit 24 and a drift signal drive circuit 25.

Of these, the signal input conversion circuit 21, as shown in FIG.
A logic conversion circuit 211 constructed using a switching transistor Q is interposed between them, and connected to a shift register 212 which is a control rod stop position signal output circuit, and similarly connected to column direction wiring P6 to P6.
11 is connected to the shift register 212 and to the power supply via a resistor R. Furthermore, the row direction wirings P4, P5 and the column direction wirings P6, P1
0, P11, all insertion position signals a ₁ ,
a ₂ , total withdrawal position signal b ₁ , b ₂ , drift position signal
c ₁ and c ₂ are extracted.

In addition, the control rod fully inserted and fully withdrawn position signal calculation circuit 22 and drift signal calculation circuit 24 are connected to NOR gates 221, 222, 241, as shown in FIG.
It is composed of

Furthermore, the control rod fully inserted and fully withdrawn position signal drive circuit 23 and drift signal drive circuit 25 include photocouplers 231, 232,
It is composed of 251.

The control rod position detection device 1 and the control rod position reading device 2 configured as described above are provided for each control rod arranged in the reactor, and the control rod position reading device 2 outputs the control rod position. The rod position signal k is applied to a computer and display device (not shown) via the control rod position processing device 3. In addition, the control rod fully inserted position output signal g, the control rod fully withdrawn position output signal h output from the control rod position reading device 2,
The drift position output signal i is applied to a measuring device (not shown).

The control rod position indicating system of this embodiment is configured as described above, and operations such as displaying the control rod position and measuring the operation time between the fully inserted and fully withdrawn positions are performed as follows.

That is, first, when displaying the control rod position.

Depending on the stop position of the control rod, a predetermined reed switch 1A shown in FIG. 2b is closed, thereby turning on the transistor Q of the logic conversion circuit 211 interposed in the row direction wiring shown in FIG. As a result, both the row direction wiring and column direction wiring connected via the currently closed reed switch 1A fall to the logic "0" level. On the other hand, both the row direction wiring and column direction wiring in which the reed switch is open are at the logic "1" level.

The signals appearing on these row direction wires and column direction wires P1 to P11 are set in a shift register 212 in parallel. For example, if the control rod is stopped at the "40" position, the row direction wiring P1 and the column direction wiring P6
As a result, the shift register 212 has "01111011111" as both are at the "0" level and the others are at the "1" level.
will be set.

In this way, the 25 stop positions from the total insertion position "00" to the total withdrawal position "48" are converted into an 11-bit logic signal k and set in the shift register 212.

On the other hand, the control rod position processing device 3 shown in FIG.
Each control rod position reading device 2 is sequentially scanned and a shift clock j is added to the shift register 212 of the accessed control rod position reading device 2.

As a result, the 11-bit logic signal k set in parallel in the shift register 212 of FIG. 4 is converted into a serial signal and taken out to the control rod position processing device 3 of FIG. The logic signal k extracted in this way is converted into display data and output to a display device (not shown) for display.

Next, when measuring the operating time from the fully inserted position to the fully withdrawn position.

When the control rod is pulled out, it first reaches the full insertion position "00", and as described above, both the row direction wiring P5 and the column direction wiring P6 fall to the "0" level. The signals a ₁ and a ₂ on the wirings P5 and P6 are applied to the control rod fully inserted and fully withdrawn position signal calculation circuit 22, that is, the NOR gate 221 shown in FIG.
It is converted into a level signal d and is applied to the control rod full insertion and full withdrawal position signal drive circuit 23.

Control rod fully inserted and fully withdrawn position signal drive circuit 2
3 is constructed as shown in FIG. 6, and when the signal d reaches the "1" level, the photocoupler 231 stops operating and its output signal g falls to the "0" level.

This output signal g is applied to a measuring device (not shown), and when this output signal g falls to the "0" level, a time measuring operation is started. Of course, this output signal g rises to the "1" level again when the control rod passes through the full insertion position "00", but the measurement operation continues.

When the control rod is further withdrawn and reaches the fully withdrawn position "48", both the row direction wiring P5 and the column direction wiring P10 fall to the "0" level, and as mentioned above, the signal e from the NOR gate 222 is activated. , the photocoupler 232 stops operating and the output signal h falls to the "0" level.

When this output signal h falls to the "0" level, the previous time measurement operation is stopped, and the operation time from the full insertion position to the full extraction position is measured. Of course, it goes without saying that the operation time from the fully withdrawn position to the fully inserted position is measured in the same manner.

Furthermore, in this example, as mentioned above,
Since the reed switch ODD, which closes when the control rod passes through each drift position, is connected between the row direction wiring P4 and the column direction wiring P11, as described above,
The signals c ₁ and c ₂ are extracted from the wirings P4 and P11, converted into a drift position signal f via the NOR gate 241, and the operation of the photocoupler 251 is stopped using this signal f, so that the obtained output signal i is When added to a measuring device, it becomes possible to measure the operation time to an intermediate position or the operation distance within a predetermined time.

As described above, according to this embodiment, although the number of bits representing the stop position of the control rod increases somewhat, the transistors only need to be interposed in the row direction wirings P1 to P5, and moreover, the control rods are completely inserted. The on/off signals required when passing through the position and the full extraction position, or the on/off signals corresponding to each drift position, can be transmitted to the predetermined locations of the existing wiring P1 to P5 without intervening new elements such as transistors and diodes. Since the control position signal can be taken out using a small number of elements, the circuit configuration is simple with a small number of elements, and a predetermined control position signal can be taken out extremely economically.

Note that the shift register 21 in the above embodiment
2. NOR gates 221, 222, 241, photocouplers 231, 232, 251, etc. are just examples, and these circuits can be used with other memory circuits,
Needless to say, it can be replaced with an arithmetic circuit, a signal separation circuit, etc.

As described above, the present invention provides an extremely economical control rod with a small number of elements, a simple circuit configuration, and the ability to display the control rod position and measure the operation time between the fully inserted and fully withdrawn positions. A position detection reading device is obtained.

[Brief explanation of drawings]

Fig. 1 is a block diagram of the main parts of a control rod position indicating system showing an embodiment of the present invention, Figs. The internal block configuration diagram of the control rod reading device, Fig. 4 is a detailed circuit diagram of its signal input conversion circuit, and Figs. 5 a and b are its control rod full insertion position, full withdrawal position signal calculation circuit, and drift position signal calculation circuit. FIGS. 6a and 6b are detailed circuit diagrams of the control rod fully inserted position, fully withdrawn position signal drive circuit, and drift position signal drive circuit. 1... Control rod position detection device, 2... Control rod position reading device, 3... Control rod position processing device, 21
...Signal input conversion circuit, 22...Control rod fully inserted,
Full withdrawal position signal calculation circuit, 23... Control rod full insertion, full withdrawal position signal drive circuit, 24... Drift signal calculation circuit, 25... Drift signal drive circuit, 211... Logic conversion circuit, 212...
...Shift register, 221, 222, 241...
NOR gate, 231, 232, 251...Hotocoupler.

Claims (1)

[Scope of Claims] 1. A matrix wiring made up of a plurality of row-direction wirings and column-direction wirings, and contacts connected to each intersection of the matrix wirings and opened and closed in accordance with each stop position of the control rod; A power supply connected to one of the row direction wiring and the column direction wiring via a resistor, and a power supply interposed in the other of the row direction wiring and the column direction wiring, respectively, and when the contact point is opened or closed, the power source is connected to the contact point. a logic conversion circuit that changes the logic of signals appearing on connected row and column wiring; and a logic conversion circuit that arranges the row wiring and column wiring in a predetermined order, and converts the arranged wiring according to the open/closed state of the contact. Based on two signals obtained from a control rod stop position signal output circuit that extracts a logic signal representing the control rod stop position, and from row and column direction wiring connected to the contacts arranged at all control rod insertion positions. It is based on two signals obtained from a control rod full insertion position calculation circuit that takes out a full insertion position signal that causes the contact to close, and from row and column direction wiring connected to the contact placed at the control rod full withdrawal position. It is equipped with a control rod full withdrawal position calculation circuit that extracts the full withdrawal position signal when the contact is closed, and it is possible to display each control rod stop position and measure the control rod operation time between the full insertion and full withdrawal positions. A control rod position detection and reading device characterized by: