JPH0115760B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to an improvement of a device for detecting a rupture accident in a water distribution pipe.

(Prior Art) When it comes to water pipes, etc., there is a risk of a bursting accident, and it is necessary to stop the water supply immediately after the accident occurs. Particularly in large cities, bursting accidents occur frequently due to road construction, etc., and the amount of water distributed through pipes is large, so prompt action is required.

FIG. 1 is a block diagram showing an example of a conventional device of this type. A flow rate detector 2 is provided at an appropriate location on the piping path 1. 3 is a flow rate converter that converts and amplifies the detected amount of the flow rate detector 2 into an electrical signal, 4 is a sampler that samples the output of the flow rate converter 3, and 5 is a storage unit that holds the sampled value until the next sampling. It is. Reference numeral 6 denotes a comparison/discriminator that compares the output of the flow rate converter 3 and the numerical value in the storage section 5.

8 is a pressure signal generator that detects the pressure in the piping path 1 and transmits an electrical signal. 9 is a sampler, 10 is a storage section, and 11 is a comparison discriminator.

In the above configuration, the discriminators 6 and 1 compare signals proportional to the flow rate and fluid pressure a predetermined time ago with signals proportional to the current flow rate and fluid pressure, respectively.
1, and when the deviation exceeds a certain set value at the same time, contacts 6a and 11a close, and a pipe rupture alarm is output.

In such conventional devices, the set value is fixed, and therefore the set value must normally be set to a value based on the maximum value of the flow rate or pressure. Therefore, when the flow rate and pressure are small and the degree of rupture is small, there is a risk that detection will be delayed or may not be detected. On the other hand, if the set value is based on a commonly used flow rate or pressure value, there is a drawback that a false alarm may be issued when the consumption amount is higher than usual due to reasons other than pipe rupture, such as a fire.

The present invention has been made in consideration of the above points, and
By setting the set value as a function (for example, proportional or square proportional) of the current flow rate or current pressure, failure to issue an alarm or false alarm can be prevented.

[Structure of the invention] (Means for solving the problem) A flow rate detector that detects the water flow rate of a water distribution pipe;
a flow rate sampling means for sampling the flow rate data from this detector at a predetermined sampling period; a flow rate data storage and holding means for storing the output from this sampling means until the next sampling period; a flow rate data comparison/determination means that compares the flow rate data of the previous sampling period with the flow rate data of the flow rate detector at the present time and generates an alarm signal when a set value is exceeded; and a fluid pressure in the water distribution pipe. a pressure transmitter for detecting pressure, a pressure sampling means for sampling pressure data from the transmitter at a predetermined sampling period, a pressure data storage and holding means for storing the output from the sampling means until the next sampling period, and a pressure data storage means for storing the output from the sampling means until the next sampling period; Pressure data of the previous sampling cycle stored in the holding means,
pressure data comparison and determination means that compares the pressure data of the pressure transmitter at the present time and generates an alarm signal when the set value is exceeded; It is provided with a set value calculation means that increases or decreases the set value of the pressure data comparing and determining means according to the increase or decrease of the flow rate data at the current time.

(Operation) When alarm signals are output from both the flow rate data comparison and determination means and the pressure data comparison and determination means, a rupture alarm for the water distribution pipe is generated.

(Example) This will be explained in detail below with reference to the drawings.

FIG. 2 is a block diagram showing a device according to the present invention, in which 13 is a set value calculator, 14 and 15 are pumps installed in parallel, and 16 is a fluid storage tank (for example, a water distribution reservoir in the case of a water utility). It is.

The flow rate detector 2 installed at an appropriate location on the piping path 1 is
It detects the fluid flow rate and generates an electrical signal proportional to this. The output of a flow rate converter 3 that converts and amplifies the output of this flow rate detector 2 is input to a sampling device 4, and the output is applied to a memory holder 5. The sampling device 4 sends the value obtained from the flow rate converter 3 to the memory holder 5 at fixed time intervals based on the sampling period, and the memory holder 5 converts the signal given from the sampling device 4 into the next one. Stored until the sampling time. This memory holder 5
The output of the flow rate converter 3 and the output of the flow rate converter 3 are added to a comparison/discrimination device 6, and the output held for a predetermined time from the memory holder 5 is subtracted from the current output of the flow rate converter 3.

On the other hand, the set value calculation device 13 is connected to the flow rate converter 3.
A set value is calculated based on the current flow rate (current flow rate) obtained from the above, and is output to the comparison/discrimination device 6.
The calculation formula for this set value differs depending on the number of pumps and the condition of the piping, but at least the set value is large when the current flow rate is large, and the set value is small when the current flow rate is small.It is a non-linear calculation formula. It may also be a formula.

Then, when the subtracted value exceeds the set value from the set value calculating device 13, the comparing and determining device 6 generates an alarm signal and closes the normally open contact 6a.

On the other hand, the pressure transmitter 8 detects the pressure of the fluid flowing through the piping line 1 and generates an electric signal proportional to this pressure.

The pressure data output from the transmitter 8 is supplied to the memory holder 10 by the sampling device 9 based on a predetermined sampling period as described above. and,
The pressure data from the previous sampling cycle stored in this memory holder 10 and the current pressure data from the pressure transmitter 8 are supplied to the comparison and discrimination device 11, and the comparison and discrimination device 11 stores the current pressure data from the pressure transmitter 8. The pressure data of the previous sampling period is subtracted from the pressure data, and when the subtracted value exceeds a preset value, an alarm signal is generated and the normally open contact 11a is closed. A pipe rupture alarm is issued when normally open contacts 6a and 11a are closed at the same time.

The operation of the apparatus shown in FIG. 2 will be explained in more detail. As described above, the flow rate of the piping line 1 is detected by the flow rate detector 2 and inputted to the sampling device 4 via the flow rate converter 3. The sampling value from this sampling station 4 is held by a memory holder 5 for a sampling time and is inputted to a comparison/discrimination device 6 as an output _Q2 . Furthermore, at this point, the current flow rate signal Q ₁ is input to the comparison/discrimination device 6 to calculate (Q ₁ −Q ₂ ), and it is determined whether or not the current flow rate signal Q 1 exceeds the set value output from the set value calculation device 13 .

On the other hand, at the same time that the flow rate detector 2 is detecting the flow rate, the pressure transmitter 8 is also detecting the fluid pressure.
P ₂ and the current signal P ₁ are input to the comparison/discrimination device 11 . The comparison/determination device 11 calculates (P ₁ -P ₂ ) and determines whether it exceeds a predetermined set value.

When the pipe line 1 is in a steady state, the deviation output (Q ₁ - Q ₂ ) or (P ₁ - P ₂ ) of the comparison/discrimination device 6 or 11
By selecting a short sampling time, the normally open contact 6a or 1 can be maintained without exceeding the set value.
1a is not closed.

Next, the flow rate of the fluid flowing into the piping line 1 increases rapidly due to activation of the pump or valve operation on the fluid supply side, and the deviation (Q ₁ - Q ₂ ) of the comparison/discrimination device 6 exceeds the set value from the set value calculation device 13. Beyond, normally open contact 6
Even if a is closed, the pressure of the fluid acts in the direction of increasing in this case, so the comparing and discriminating device 1
The deviation (P ₁ -P ₂ ) of 1 does not exceed the predetermined set value, the normally open contact 11a does not close, and no false alarm is output.

Moreover, contrary to the above, even if the pressure of the fluid in the piping line 1 decreases due to stopping the pump or operating a valve on the fluid supply side, in this case, the flow rate will not increase rapidly, so the normally open contact 11 will close. Also, the normally open contact 6a does not close, and no false alarm is output.

Next, when a valve or the like is suddenly operated in the opening direction on the fluid demand side, the flow rate of the fluid increases rapidly and its pressure decreases. In this case, the deviation (P ₁ - P ₂ ) of the comparison/discrimination device 11 exceeds a certain negative value and the normally open contact 1
1a is closed, but due to the rapid increase in flow rate, the set value from the set value calculation device 13 also becomes a large value, so the deviation (Q ₁ -Q) of the comparison/discrimination device 6 does not exceed the set value and remains constant. The open contact 6a does not close, and no false alarm is output.

However, if a bursting accident occurs at a certain point in the pipe line 1, the flow rate increases rapidly and the pressure decreases, as described above. In this case, the deviation (P ₁ - P ₂ ) of the comparison/discrimination device 11 exceeds the predetermined set value, and the normally open contact 1
1a is closed, and the deviation of the comparison/discrimination device 6 (Q ₁ −Q ₂ )
is so large that it exceeds the set value from the set value calculation device 13 that increases with the increase in flow rate, and the normally open contact 6a closes, causing an alarm to be issued.

Here, the calculation formula of the set value calculation device 13 will be explained with reference to FIG. When determining the calculation formula, it depends on the number of pumps and the condition of pipe line 1, but as shown in Figure 3, the flow rate fluctuation due to changes in the line resistance curve is more likely to occur at large flow rates than at small flow rates. is larger, so at least when the flow rate is large,
The set value is also large, and when the flow rate is small, the set value is also small.

In Figure 3, the flow rate is Q ₂ and the pipe resistance curve is 1.
8, the pump operating point is pump head curve 17'
is the intersection of the pipe resistance curve 18, but if the pipe resistance curve shifts to 18' due to a pipe rupture, etc.
The pump operating point is the intersection of the pump head curve 17' and the line resistance curve 18', and the flow rate fluctuation becomes _ΔQ2 .
Similarly, when the flow rate is Q ₁ , the flow rate fluctuation is △Q ₁ ,
As is clear from the figure, if Q ₁ < Q ₂ , then △Q ₁ < △
_Q2 .

Another embodiment of the present invention will be explained with reference to the block diagram of FIG. The difference from the case of FIG. 2 is that the pumps 14 and 15 are connected in series, and that a set value calculator 17 is provided in the pressure detection system accordingly.

Figure 5 is an operating characteristic diagram for the configuration shown in Figure 4.As is clear from the figure, when the pumps are installed in series, the pressure fluctuation is greater at large pressure than at small pressure, where △P ₁ < △P ₂ . Since this value is larger, the set value is configured to be changed depending on the current pressure.

[Effects of the Invention] As described above, according to the present invention, the set value changes depending on the state of the flow rate, so it is possible to prevent alarm failures and false alarms. Incidentally, in the past, the set value was fixed, so if the set value is too large, even if a small pipe rupture occurs when the flow rate or pressure is small, detection may be delayed or may not be detected. It was hot. On the other hand, if the set value is too small, a false alarm may be issued even if the flow rate increases rapidly due to a fire, etc., rather than a pipe rupture, resulting in a pressure drop. Accordingly, it is possible to obtain a burst warning device that does not have such drawbacks.

[Brief explanation of drawings]

Figure 1 is a block diagram showing a conventional device; Figure 2 is a block diagram showing a conventional device;
Figure 3 is a block diagram of a device according to the present invention, Figure 3 is a characteristic diagram showing a pump lift curve and line resistance curve for explaining the invention, and Figure 4 is a block diagram showing another embodiment of the invention. , FIG. 5 is a characteristic diagram showing a pump lift curve and a pipe resistance curve for explaining the apparatus shown in FIG. 4. 1... Piping line, 2... Flow rate detector, 3... Flow rate converter, 4... Sampling device, 5... Storage section,
6... Comparison discriminator, 8... Pressure signal transmitter, 9...
...Sampler, 10...Storage unit, 11...Comparison/discriminator, 13, 17...Set value calculator.

Claims (1)

[Claims] 1. A flow rate detector that detects the water flow rate of the water distribution pipe, a flow rate sampling means that samples the flow rate data from this detector at a predetermined sampling period, and a flow rate that stores the output from this sampling means until the next sampling period. A data storage holding means compares the flow rate data of the previous sampling cycle stored in the storage holding means with the current flow rate data of the flow rate detector, and generates an alarm signal when a set value is exceeded. a flow rate data comparison/determination means; a pressure transmitter for detecting the fluid pressure in the water distribution pipe; a pressure sampling means for sampling pressure data from the transmitter at a predetermined sampling period; The pressure data storage means stores the pressure data up to the sampling period, and compares the pressure data of the previous sampling period stored in this storage storage means with the pressure data of the pressure transmitter at the present time, and determines whether the pressure exceeds the set value. The set value of the pressure data comparison and discrimination means for generating an alarm signal when an alarm signal is generated is increased or decreased according to the increase or decrease of the flow rate data at the current time, or the set value of the pressure data comparison and discrimination means is changed at the current time. set value calculation means for increasing or decreasing according to an increase or decrease in the flow rate data, and generating a rupture alarm for the water distribution pipe when an alarm signal is outputted from both the flow rate data comparison and determination means and the pressure data comparison and determination means. This is a distinctive feature of the water pipe rupture warning device.