CN111272247A - Real-time water consumption data acquisition method and terminal - Google Patents

Abstract

The invention discloses a real-time water consumption data acquisition method and a terminal, wherein a reed switch is scanned, whether the accumulated number of pulses of the reed switch reaches a preset number of pulses or not is judged, if yes, the current time is recorded, a camera is started to shoot to obtain real-time water consumption data, and otherwise, the reed switch is continuously scanned; the invention can achieve better real-time performance by pulse triggering of the reed switch, trigger the camera to take a picture when the accumulated number of pulses reaches the preset number of pulses, acquire the dial plate image by the photographic technology, and recognize the water consumption number in the dial plate image to obtain more accurate water consumption measurement, thereby realizing the remote acquisition of water consumption data with high real-time performance and high accuracy.

Description

Real-time water consumption data acquisition method and terminal

Technical Field

The invention relates to the technical field of measurement, in particular to a real-time water consumption data acquisition method and a terminal.

Background

A typical conventional rotary wing water meter dial typically includes a rotary pointer indication and a digital code display. Therefore, calculating the number of turns of the indicating pointer or the number displayed by the identification code meter is a scheme used for remote meter reading of a typical common rotary wing type water meter.

On one hand, the reed switch can be opened and closed under the action of the magnetic pointer, and a pulse signal is formed under the coordination of an external circuit. When the pointer on the dial of the common rotary-wing water meter is replaced by a magnetic pointer, the number of rotation turns of the magnetic pointer is in proportion to the water consumption, so that the number of pulses formed by the reed switch collected by the MCU can reflect the water metering amount of the water meter in real time. However, due to the specific 'water hammer' effect of tap water, the pointer of the water meter swings clockwise and anticlockwise, the phenomenon can cause the 'opening and closing' misoperation of the reed switch, and the accuracy of pulse acquisition of the reed switch still has problems in the actual acquisition process.

On the other hand, by using the photographic technology to obtain the dial image and identifying the water consumption number in the dial image, more accurate water quantity metering can be obtained. In a non-real-time environment, accurate metering data can be satisfactorily obtained by taking a picture once a day or a month. However, in a real-time environment where continuous startup shooting or frequent snapshot is required, the energy consumption caused by the camera system causes energy pressure that is difficult to bear for the water meter collector powered by the battery.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: the method and the terminal for acquiring the water consumption data in real time are provided to realize remote acquisition of the water consumption data with high real-time performance and high accuracy.

In order to solve the technical problems, the invention adopts the technical scheme that:

a real-time water use data acquisition method comprises the following steps:

s1, scanning a reed switch;

s2, judging whether the accumulated number of the pulses of the reed pipe reaches the preset number of pulses, if so, executing a step S3, otherwise, returning to the step S1;

and S3, recording the current time, and starting the camera to take a picture to obtain real-time water consumption data.

In order to solve the technical problem, the invention adopts another technical scheme as follows:

a real-time water consumption data acquisition terminal comprises a memory, a processor and a computer program which is stored on the memory and can run on the processor, wherein the processor executes the computer program to realize the following steps:

s1, scanning a reed switch;

s2, judging whether the accumulated number of the pulses of the reed pipe reaches the preset number of pulses, if so, executing a step S3, otherwise, returning to the step S1;

and S3, recording the current time, and starting the camera to take a picture to obtain real-time water consumption data.

The invention has the beneficial effects that: a real-time water consumption data acquisition method and a terminal achieve better real-time performance through pulse triggering of a reed switch, trigger a camera to take a picture when the accumulated number of pulses reaches a preset number of pulses, acquire a dial plate image through a photographic technology, and recognize water consumption numbers in the dial plate image to obtain more accurate water consumption measurement, thereby realizing remote acquisition of water consumption data with high real-time performance and high accuracy.

Drawings

FIG. 1 is a schematic diagram of a main flow of a real-time water consumption data acquisition method according to an embodiment of the present invention;

FIG. 2 is a schematic flow chart of a first reed switch, a second reed switch and a magnetic pointer according to an embodiment of the present invention;

FIG. 3 is a schematic flow chart of a real-time water consumption data acquisition method according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a real-time water consumption data acquisition terminal according to an embodiment of the present invention.

Description of reference numerals:

1. a real-time water consumption data acquisition terminal; 2. a processor; 3. a memory.

Detailed Description

In order to explain technical contents, achieved objects, and effects of the present invention in detail, the following description is made with reference to the accompanying drawings in combination with the embodiments.

Referring to fig. 1 to 3, a real-time water consumption data collecting method includes the steps of:

s1, scanning a reed switch;

s2, judging whether the accumulated number of the pulses of the reed pipe reaches the preset number of pulses, if so, executing a step S3, otherwise, returning to the step S1;

and S3, recording the current time, and starting the camera to take a picture to obtain real-time water consumption data.

From the above description, the beneficial effects of the present invention are: the pulse through the reed switch triggers in order to reach better real-time to when the pulse accumulative number reaches the preset number of pulses, trigger the camera and shoot, obtain the dial plate image through photographic technique, and discern the water use number wherein, in order to obtain more accurate measurement water yield, thereby realized the long-range collection of the water use data of high real-time and high accuracy.

Further, the step S1 is specifically:

scanning a double-reed-tube assembly, wherein the double-reed-tube assembly comprises a first reed tube and a second reed tube which are perpendicular to each other, and the first reed tube and the second reed tube are sequentially positioned on a rotating path of a magnetic pointer rotating clockwise;

the step S2 specifically includes:

judging whether any reed switch in the double reed switch assembly generates pulses, if so, judging whether the generated pulses can form effective pulse turns, if so, accumulating and calculating the effective pulse turns, wherein the effective pulse turns refer to that the magnetic pointer sequentially triggers the first reed switch and the second reed switch and triggers the first reed switch again in the clockwise rotation process, and the time from triggering the first reed switch to triggering the second reed switch is shorter than the time from triggering the second reed switch to triggering the first reed switch again;

and judging whether the number of effective pulse turns of the reed pipe reaches the preset number of pulse turns, if so, executing the step S3.

It can be known from the above description that the pulse is gathered to the two dry reed pipe subassemblies of mutually perpendicular installation, because the malfunction that "water hammer" effect caused can't form the effectual effective water metering of round, consequently can effectively overcome the malfunction that "water hammer" effect caused through effective pulse number of rounds to effectual reduction collection error is with the degree of accuracy that improves the water metering.

Further, in the step S2, "it is determined whether the number of effective pulse turns of the reed pipe reaches a preset number of pulse turns, if yes, the step S3" is executed specifically as follows:

judging whether the number of effective pulse turns of the reed pipe reaches the preset number of pulse turns, if so, judging whether the reed pipe is in a pulse stop state, and if so, executing a step S3;

if the effective pulse number of the reed pipe does not reach the preset pulse number, returning to the step S1;

and if the reed switch is not in the pulse stop state, continuously judging whether the generated pulse can form an effective pulse circle number.

From the above description, the number of effective pulse turns is used as a threshold condition for starting the camera, rather than starting the camera when the preset number of pulse turns is reached, since the reed switch is not in the pulse stop state, and pulses are continuously generated on the reed switch, it is indicated that the user is still using water, and when the reed switch is in the pulse stop state, it indicates that the user stops using water, and at the moment, the camera is started again, so that the energy consumption caused by the work of the camera is saved as much as possible under the condition that the real-time performance of water data acquisition is not influenced.

Further, the double reed pipe assembly and the magnetic pointer in the step S1 are installed on a 0.01 cubic meter scale;

in the step S2, "judging whether the number of effective pulse turns of the reed pipe reaches a preset number of pulse turns, if yes, executing a step S3" specifically:

judging whether the number of effective pulse turns of the reed pipe is greater than 10, if so, saving decimal point data of water consumption, otherwise, returning to the step S1;

and judging whether the number of effective pulse turns of the reed switch is more than 100, if so, refreshing the decimal point data of the water consumption, and then executing the step S3, otherwise, returning to the step S1.

From the above description, since the double reed pipe assembly and the magnetic pointer are installed at the position of 0.01 cubic meter scale, 10 turns are 0.1 ton, and 100 turns are 1 ton, that is, the integral digit of the code table jumps once when the code table rotates clockwise by 100 turns, which is used as the threshold condition for starting the camera, so as to avoid that the camera starts to work when the integral digit of the code table does not jump, thereby saving the battery energy.

Further, the step S1 further includes: a scan timer;

the step S2 specifically includes:

and judging whether the timing time of the timer reaches the preset photographing time, if so, executing the step S3, otherwise, judging whether the accumulated pulse count of the reed pipe reaches the preset pulse number, if so, executing the step S3, otherwise, returning to the step S1.

From the above description, the preset photographing time can be day, month and year, so that the camera identifies the code table image at the 0 point at the end of day, month and year to form the assessment data, so as to meet the requirement of the water department enterprise on the day, month and year measurement and freezing data.

Referring to fig. 4, a real-time water consumption data acquisition terminal includes a memory, a processor, and a computer program stored in the memory and capable of running on the processor, wherein the processor executes the computer program to implement the following steps:

s1, scanning a reed switch;

s2, judging whether the accumulated number of the pulses of the reed pipe reaches the preset number of pulses, if so, executing a step S3, otherwise, returning to the step S1;

and S3, recording the current time, and starting the camera to take a picture to obtain real-time water consumption data.

From the above description, the beneficial effects of the present invention are: the pulse through the reed switch triggers in order to reach better real-time to when the pulse accumulative number reaches the preset number of pulses, trigger the camera and shoot, obtain the dial plate image through photographic technique, and discern the water use number wherein, in order to obtain more accurate measurement water yield, thereby realized the long-range collection of the water use data of high real-time and high accuracy.

Further, when the processor executes the step S1 of the computer program, the following steps are specifically implemented:

scanning a double-reed-tube assembly, wherein the double-reed-tube assembly comprises a first reed tube and a second reed tube which are perpendicular to each other, and the first reed tube and the second reed tube are sequentially positioned on a rotating path of a magnetic pointer rotating clockwise;

when the processor executes the step S2 of the computer program, the following steps are specifically implemented:

judging whether any reed switch in the double reed switch assembly generates pulses, if so, judging whether the generated pulses can form effective pulse turns, if so, accumulating and calculating the effective pulse turns, wherein the effective pulse turns refer to that the magnetic pointer sequentially triggers the first reed switch and the second reed switch and triggers the first reed switch again in the clockwise rotation process, and the time from triggering the first reed switch to triggering the second reed switch is shorter than the time from triggering the second reed switch to triggering the first reed switch again;

and judging whether the number of effective pulse turns of the reed pipe reaches the preset number of pulse turns, if so, executing the step S3.

It can be known from the above description that the pulse is gathered to the two dry reed pipe subassemblies of mutually perpendicular installation, because the malfunction that "water hammer" effect caused can't form the effectual effective water metering of round, consequently can effectively overcome the malfunction that "water hammer" effect caused through effective pulse number of rounds to effectual reduction collection error is with the degree of accuracy that improves the water metering.

Further, the processor executes the step S2 of the computer program to determine whether the number of effective pulse turns of the reed pipe reaches a preset number of pulse turns, and if so, executes the step S3 "to specifically implement the following steps:

judging whether the number of effective pulse turns of the reed pipe reaches the preset number of pulse turns, if so, judging whether the reed pipe is in a pulse stop state, and if so, executing a step S3;

if the effective pulse number of the reed pipe does not reach the preset pulse number, returning to the step S1;

and if the reed switch is not in the pulse stop state, continuously judging whether the generated pulse can form an effective pulse circle number.

From the above description, the number of effective pulse turns is used as a threshold condition for starting the camera, rather than starting the camera when the preset number of pulse turns is reached, since the reed switch is not in the pulse stop state, and pulses are continuously generated on the reed switch, it is indicated that the user is still using water, and when the reed switch is in the pulse stop state, it indicates that the user stops using water, and at the moment, the camera is started again, so that the energy consumption caused by the work of the camera is saved as much as possible under the condition that the real-time performance of water data acquisition is not influenced.

Further, the double reed pipe assembly and the magnetic pointer in the step S1 are installed on a 0.01 cubic meter scale;

the processor executes the computer program in step S2 to determine whether the number of effective pulse turns of the reed pipe reaches a preset number of pulse turns, and if so, executes step S3 to specifically implement the following steps:

judging whether the number of effective pulse turns of the reed pipe is greater than 10, if so, saving decimal point data of water consumption, otherwise, returning to the step S1;

and judging whether the number of effective pulse turns of the reed switch is more than 100, if so, refreshing the decimal point data of the water consumption, and then executing the step S3, otherwise, returning to the step S1.

From the above description, since the double reed pipe assembly and the magnetic pointer are installed at the position of 0.01 cubic meter scale, 10 turns are 0.1 ton, and 100 turns are 1 ton, that is, the integral digit of the code table jumps once when the code table rotates clockwise by 100 turns, which is used as the threshold condition for starting the camera, so as to avoid that the camera starts to work when the integral digit of the code table does not jump, thereby saving the battery energy.

Further, the processor, when executing the step S1 of the computer program, further includes implementing the following steps:

a scan timer;

when the processor executes the step S2 of the computer program, the following steps are specifically implemented:

and judging whether the timing time of the timer reaches the preset photographing time, if so, executing the step S3, otherwise, judging whether the accumulated pulse count of the reed pipe reaches the preset pulse number, if so, executing the step S3, otherwise, returning to the step S1.

From the above description, the preset photographing time can be day, month and year, so that the camera identifies the code table image at the 0 point at the end of day, month and year to form the assessment data, so as to meet the requirement of the water department enterprise on the day, month and year measurement and freezing data.

Referring to fig. 1 to fig. 3, a first embodiment of the present invention is:

a real-time water use data acquisition method comprises the following steps:

s1, scanning a reed switch;

in step S1 of the present embodiment, the dual reed pipe assembly and the timer are scanned simultaneously. As shown in fig. 2, the double reed pipe assembly includes a first reed pipe and a second reed pipe that are perpendicular to each other, the first reed pipe and the second reed pipe are sequentially located on a rotation path where a magnetic pointer rotates clockwise, and the double reed pipe assembly and the magnetic pointer in step S1 are installed on a scale of 0.01 cubic meter, where the first reed pipe and the second reed pipe are connected to the processor through a pulse interface.

S2, judging whether the pulse accumulated number of the reed switch reaches the preset pulse number, if so, executing a step S3, otherwise, returning to the step S1;

as shown in fig. 3, step S2 in this embodiment is specifically as follows:

judging whether the timing time of the timer reaches the preset photographing time, if so, executing the step S3;

if not, judging whether any reed pipe in the double-reed pipe assembly generates pulse, if so, judging whether the generated pulse can form effective pulse turns, if so, performing accumulation calculation on the effective pulse turns, wherein the effective pulse turns refer to that the magnetic pointer sequentially triggers the first reed pipe and the second reed pipe in the clockwise rotation process and triggers the first reed pipe again, and the time from triggering the first reed pipe to triggering the second reed pipe is less than the time from triggering the second reed pipe to triggering the first reed pipe again;

if none of the reed switches in the dual reed switch assembly generates a pulse, or the generated pulse cannot form a valid number of pulse turns, returning to step S1;

judging whether the number of effective pulse turns of the reed pipe is greater than 10, if so, saving decimal point data of water consumption, otherwise, returning to the step S1;

and judging whether the number of effective pulse turns of the reed switch is more than 100, if so, refreshing decimal point data of water consumption, and then executing the step S3, otherwise, returning to the step S1.

And judging whether the reed switch is in a pulse stop state, if so, executing a step S3, otherwise, returning to the step of judging whether the generated pulse can form effective pulse turns.

Otherwise, judging whether the pulse accumulated number of the reed switch reaches the preset pulse number, if so, executing the step S3, otherwise, returning to the step S1.

And S3, recording the current time, and starting the camera to take a picture to obtain real-time water consumption data.

The double reed pipe assembly and the magnetic pointer are arranged on a scale of 0.01 cubic meter, 10 circles are 0.1 ton, 100 circles are measured to be 1 ton, namely, the integral digits of the code table jump once when the double reed pipe assembly and the magnetic pointer rotate clockwise by 100 circles, so that the camera can shoot and recognize at least on the premise of one ton of water consumption.

Referring to fig. 2, there are generally four cases:

(1) and under the normal condition, the magnetic pointer rotates clockwise, triggers first tongue tube, second tongue tube in proper order and triggers first tongue tube again to form the effectual effective water metering of round.

(2) When the tiny water hammer effect causes misoperation, the magnetic pointer only spans the first reed pipe, and then swings under the first reed pipe or the second reed pipe, so that the magnetic pointer only causes the misoperation of opening and closing the first reed pipe or the second reed pipe, and a circle of effective water metering cannot be formed.

(3) When the 'water hammer' with large effect causes malfunction, the magnetic pointer sequentially spans the first reed pipe and the second reed pipe in the swinging process and returns to swing through the second reed pipe and the first reed pipe, and a circle of effective water metering cannot be formed.

(4) When the magnetic pointer swings in the non-reed pipe area due to the water hammer effect, no pulse signal is generated, and a circle of effective water metering cannot be formed.

Therefore, the false action caused by the water hammer effect cannot form a circle of effective water metering, so that the false action caused by the water hammer effect can be effectively overcome through the number of effective pulse circles, the acquisition error is effectively reduced, and the accuracy of water metering is improved.

Referring to fig. 4, a second embodiment of the present invention is:

a real-time water consumption data acquisition terminal 1 comprises a memory 3, a processor 2 and a computer program which is stored on the memory 3 and can run on the processor 2, wherein the steps in the first embodiment are realized when the processor 2 executes the computer program.

In summary, according to the real-time water consumption data acquisition method and the terminal provided by the invention, on one hand, the advantage of low power consumption acquired by the reed pipe pulse trigger processor is exerted, and the false operation caused by the water hammer effect is effectively overcome by adopting the double reed pipe assemblies which are vertically arranged and combining the measurement method of the number of effective pulse turns, so that the accuracy of water consumption metering is improved; on the other hand, the precision advantage of image identification and acquisition and the advantage of anti-magnetic interference are combined, and the problem of high energy consumption of image monitoring is ingeniously avoided by means of an effective pulse triggering mechanism of the reed switch; meanwhile, presetting photographing time to form assessment data to match the requirements of the water department enterprise on daily, monthly and annual metering freezing data; therefore, the remote acquisition of the water consumption data with low energy consumption, high real-time performance and high accuracy is realized.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all equivalent changes made by using the contents of the present specification and the drawings, or applied directly or indirectly to the related technical fields, are included in the scope of the present invention.

Claims (10)

1. A real-time water use data acquisition method is characterized by comprising the following steps:

s1, scanning a reed switch;

s2, judging whether the accumulated number of the pulses of the reed pipe reaches the preset number of pulses, if so, executing a step S3, otherwise, returning to the step S1;

and S3, recording the current time, and starting the camera to take a picture to obtain real-time water consumption data.

2. The real-time water use data acquisition method according to claim 1, wherein the step S1 specifically comprises:

scanning a double-reed-tube assembly, wherein the double-reed-tube assembly comprises a first reed tube and a second reed tube which are perpendicular to each other, and the first reed tube and the second reed tube are sequentially positioned on a rotating path of a magnetic pointer rotating clockwise;

the step S2 specifically includes:

judging whether any reed switch in the double reed switch assembly generates pulses, if so, judging whether the generated pulses can form effective pulse turns, if so, accumulating and calculating the effective pulse turns, wherein the effective pulse turns refer to that the magnetic pointer sequentially triggers the first reed switch and the second reed switch and triggers the first reed switch again in the clockwise rotation process, and the time from triggering the first reed switch to triggering the second reed switch is shorter than the time from triggering the second reed switch to triggering the first reed switch again;

and judging whether the number of effective pulse turns of the reed pipe reaches the preset number of pulse turns, if so, executing the step S3.

3. The method as claimed in claim 2, wherein the step S2 is performed by determining whether the number of valid pulses of the reed pipe reaches a preset number of pulses, and if so, performing the step S3 specifically as follows:

judging whether the number of effective pulse turns of the reed pipe reaches the preset number of pulse turns, if so, judging whether the reed pipe is in a pulse stop state, and if so, executing a step S3;

if the effective pulse number of the reed pipe does not reach the preset pulse number, returning to the step S1;

and if the reed switch is not in the pulse stop state, continuously judging whether the generated pulse can form an effective pulse circle number.

4. The method as claimed in claim 2, wherein the double reed pipe assembly and the magnetic pointer of step S1 are installed on a 0.01 cubic meter scale;

in the step S2, "judging whether the number of effective pulse turns of the reed pipe reaches a preset number of pulse turns, if yes, executing a step S3" specifically:

judging whether the number of effective pulse turns of the reed pipe is greater than 10, if so, saving decimal point data of water consumption, otherwise, returning to the step S1;

and judging whether the number of effective pulse turns of the reed switch is more than 100, if so, refreshing the decimal point data of the water consumption, and then executing the step S3, otherwise, returning to the step S1.

5. The real-time water use data acquisition method according to claim 1, wherein the step S1 further comprises: a scan timer;

the step S2 specifically includes:

and judging whether the timing time of the timer reaches the preset photographing time, if so, executing the step S3, otherwise, judging whether the accumulated pulse count of the reed pipe reaches the preset pulse number, if so, executing the step S3, otherwise, returning to the step S1.

6. A real-time water use data acquisition terminal comprises a memory, a processor and a computer program which is stored on the memory and can run on the processor, and is characterized in that the processor executes the computer program to realize the following steps:

s1, scanning a reed switch;

s2, judging whether the accumulated number of the pulses of the reed pipe reaches the preset number of pulses, if so, executing a step S3, otherwise, returning to the step S1;

and S3, recording the current time, and starting the camera to take a picture to obtain real-time water consumption data.

7. The real-time water use data acquisition terminal according to claim 6, wherein the processor implements the following steps when executing the step S1 of the computer program:

scanning a double-reed-tube assembly, wherein the double-reed-tube assembly comprises a first reed tube and a second reed tube which are perpendicular to each other, and the first reed tube and the second reed tube are sequentially positioned on a rotating path of a magnetic pointer rotating clockwise;

when the processor executes the step S2 of the computer program, the following steps are specifically implemented:

judging whether any reed switch in the double reed switch assembly generates pulses, if so, judging whether the generated pulses can form effective pulse turns, if so, accumulating and calculating the effective pulse turns, wherein the effective pulse turns refer to that the magnetic pointer sequentially triggers the first reed switch and the second reed switch and triggers the first reed switch again in the clockwise rotation process, and the time from triggering the first reed switch to triggering the second reed switch is shorter than the time from triggering the second reed switch to triggering the first reed switch again;

and judging whether the number of effective pulse turns of the reed pipe reaches the preset number of pulse turns, if so, executing the step S3.

8. The real-time water consumption data acquisition terminal as claimed in claim 7, wherein the processor executes step S2 of the computer program to determine whether the number of valid pulse turns of the reed pipe reaches a preset number of pulse turns, and if so, executes step S3 "to specifically implement the following steps:

judging whether the number of effective pulse turns of the reed pipe reaches the preset number of pulse turns, if so, judging whether the reed pipe is in a pulse stop state, and if so, executing a step S3;

if the effective pulse number of the reed pipe does not reach the preset pulse number, returning to the step S1;

and if the reed switch is not in the pulse stop state, continuously judging whether the generated pulse can form an effective pulse circle number.

9. The real-time water use data acquisition terminal as claimed in claim 7, wherein said double reed pipe assembly and said magnetic pointer in step S1 are installed on a 0.01 cubic meter scale;

the processor executes the computer program in step S2 to determine whether the number of effective pulse turns of the reed pipe reaches a preset number of pulse turns, and if so, executes step S3 to specifically implement the following steps:

judging whether the number of effective pulse turns of the reed pipe is greater than 10, if so, saving decimal point data of water consumption, otherwise, returning to the step S1;

and judging whether the number of effective pulse turns of the reed switch is more than 100, if so, refreshing the decimal point data of the water consumption, and then executing the step S3, otherwise, returning to the step S1.

10. The real-time water usage data collection terminal of claim 6, wherein the processor executing the step S1 of the computer program further comprises implementing the steps of:

a scan timer;

when the processor executes the step S2 of the computer program, the following steps are specifically implemented:

and judging whether the timing time of the timer reaches the preset photographing time, if so, executing the step S3, otherwise, judging whether the accumulated pulse count of the reed pipe reaches the preset pulse number, if so, executing the step S3, otherwise, returning to the step S1.

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