CN109188495B - Method for open-loop type synchronous measurement of effective decay constant and radium concentration in water - Google Patents

Abstract

In the measuring device, an air inlet pipe sleeve and an air outlet pipe sleeve are respectively arranged on a bottle cap, an air inlet pipe is inserted on the air inlet pipe sleeve, an air outlet pipe is inserted on the air outlet pipe sleeve, the air outlet pipe is connected with an air inlet end of an air pump, an air outlet end of the air pump is connected with an air inlet end of a three-way electromagnetic valve, a first air outlet end of the three-way electromagnetic valve is connected with an air inlet end of a radon measuring instrument, a second air outlet end of the three-way electromagnetic valve is communicated with the atmospheric environment, and an air outlet end of the radon measuring instrument is connected with a flowmeter. During measurement, a measuring device filled with a water sample to be measured is placed in a constant-temperature environment, the air pump controls air to enter the air inlet pipe to bubble at a certain flow rate, radon in the water sample to be measured is carried out, enters the air pump through the air outlet pipe and then enters the radon measuring instrument to measure the gas radon concentration, and the radium concentration in the water sample is calculated according to the ambient temperature, the volume of the water sample to be measured, the flow rate of the air pump and the reading of the radon measuring instrument.

Description

Method for open-loop synchronous measurement of effective decay constant and radium concentration in water

Technical Field

The invention relates to a nuclear radiation detection technology, in particular to a method for synchronously measuring an effective decay constant and radium concentration in water in an open loop mode.

Background

Radium (Ra-226) is a very toxic osteogenic alpha radionuclide, and its massive deposition in vivo can induce bone cancer or leukemia, thus endangering human health. Radium (Ra-226) has generally higher activity in underground water, and is 1-2 orders of magnitude higher than that of general surface water (river water, lake water, seawater and the like); drinking water sources in many regions of the world are underground water, and underground water in some regions naturally contains high-concentration radium elements or a large amount of radium elements are activated and released into the underground water along with exploitation of different mineral products such as uranium mines and the like, so that great potential safety hazards exist when people use the underground water as the drinking water source, and the concentration of the radium elements contained in the local underground water needs to be monitored for a long time when the drinking water source is selected. In the prior art, the measuring device and the measuring method for the radium element concentration in water are complex and long in measuring time, and a device and a method for rapidly measuring the radium element concentration in water are needed.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provide the method for synchronously measuring the effective decay constant and the radium concentration in water in an open loop manner, and the method can be used for quickly obtaining the accurate radium concentration in water.

The technical scheme of the invention is as follows: the method for synchronously measuring the effective decay constant and the radium concentration in water in an open-loop manner is based on a device for synchronously measuring the effective decay constant and the radium concentration in water in an open-loop manner, and the device comprises a water sample measuring bottle, a bottle cap, an air inlet pipe sleeve, an air outlet pipe sleeve, an air inlet pipe, an air outlet pipe, an air pump, a radon measuring instrument, a flowmeter and a three-way electromagnetic valve.

The air inlet pipe sleeve and the air outlet pipe sleeve are respectively arranged on the bottle cap, the air inlet pipe is inserted into the air inlet pipe sleeve, the air outlet pipe is inserted into the air outlet pipe sleeve, the air outlet pipe is connected with the air inlet end of the air pump through a hose, the air outlet end of the air pump is connected with the air inlet end of the three-way electromagnetic valve through a hose, the first air outlet end of the three-way electromagnetic valve is connected with the air inlet end of the radon detector through a hose, the second air outlet end of the three-way electromagnetic valve is communicated with the atmospheric environment, and the air outlet end of the radon detector is connected with the flowmeter through a hose;

the method comprises a measuring process and a calculating process, and comprises the following specific steps:

first, measurement process

A. Placing a device for synchronously measuring the effective decay constant and the radium concentration in water in an open-loop mode in a constant-temperature environment, and measuring the environment temperature;

B. pouring a water sample to be detected into the water sample measuring bottle, tightly covering the bottle cap, wherein the air outlet of the air inlet pipe is positioned in the water sample to be detected and close to the bottle bottom of the water sample measuring bottle, and the air inlet of the air outlet pipe is positioned on the liquid level of the water sample to be detected;

C. opening a second air outlet end of the three-way electromagnetic valve, closing a first air outlet end of the three-way electromagnetic valve, starting the air pump, controlling the flow rate of the air pump, enabling air to enter the sample water to be detected for bubbling through the air inlet pipe, simultaneously carrying out radon in the sample water to be detected, entering the three-way electromagnetic valve through the air outlet pipe, and then entering an atmospheric environment from the second air outlet end of the three-way electromagnetic valve, wherein the radon concentration in the air path can be considered to be 0 after the air pump is started for 5-30 minutes due to the very large flow rate of the air pump;

D. closing a second air outlet end of the three-way electromagnetic valve, opening a first air outlet end of the three-way electromagnetic valve, controlling the air pump to regulate the flow rate to be small by acquiring the reading of the flow meter, so that air enters the water sample to be tested through the air inlet pipe to bubble, simultaneously carrying out radon in the water sample to be tested, enters the three-way electromagnetic valve through the air outlet pipe, enters the radon detector from the first air outlet end of the three-way electromagnetic valve, and then enters the atmospheric environment through the flow meter; when the flow rate of the air pump is reduced, the flow rate of the air pump is kept moderate, so that the radon concentration in the measuring cavity of the radon measuring instrument and the gaseous radon concentration in the water sample measuring bottle synchronously change.

Second, calculating process

And calculating radium concentration in the water sample according to the environment temperature, the volume of the water sample to be detected, the flow rate of the air pump and the reading of the radon measuring instrument.

Radon in the water sample to be detected comes from decay of radium in water, and the volume of the water sample to be detected is V, and the activity of the radium in water is A_RaAnd then the radium concentration in water is C_RaComprises the following steps:

C_Ra＝A_Ra/V (1)

radon concentration C 'in water'_RnThe change rule is as follows:

in the formula of_RnIs the decay constant, C, of radon_RnThe concentration of the gaseous radon in the water sample measuring bottle is measured, L is the flow rate of the air pump, and lambda is_lIs the leakage coefficient, V₁Is the volume of the gas path from the water sample measuring bottle to the measuring cavity of the emanometer. Because the air pump flow rate is great, can regard as the gaseous radon concentration that the water sample measuring flask arrived the emanometer measuring chamber the same.

According to the temperature during measurement, the concentration ratio X of water radon to gaseous radon during balance can be obtained by looking up a table, and the concentration ratio X comprises the following components:

C'_Rn＝XC_Rn (3)

substituting formula (3) into formula (2) to obtain:

order to

In the formula of_eIs the effective decay constant.

Equation (4) can be simplified as:

the solution of equation (6) is:

the measurement process adopts a short time interval measurement, namely one measurement in 2-10 minutes, and a plurality of periods are measured until the radon concentration tends to a constant value.

And (3) defining the radon concentration data of a plurality of measured periods as the radon concentration of the midpoint of the plurality of periods, and fitting nonlinear data by using a formula (7) to synchronously obtain the radium concentration and the effective decay constant in the water.

Compared with the prior art, the invention has the following advantages:

1. the measuring device provided by the invention has the advantages of simple structure, convenience in operation and short measuring time.

2. The measuring method provided by the invention has the advantages that the effective decay constant is synchronously calculated, the calculation process of radium concentration in water is simple, the calculation result is accurate, the healthy drinking water standard can be established for the country through long-term continuous monitoring and analysis of radium concentration in the groundwater sample of a certain area, and the basis is provided for water pollution treatment, national disease prevention and treatment, water for agriculture and animal husbandry and the like, so that the groundwater environment and the safety of drinking water of residents are ensured.

The detailed structure of the present invention will be further described with reference to the accompanying drawings and the detailed description.

Drawings

FIG. 1 is a schematic structural diagram of an open-loop type device for synchronously measuring an effective decay constant and radium concentration in water.

Detailed Description

The device for synchronously measuring the effective decay constant and the radium concentration in water in an open-loop manner comprises a water sample measuring bottle 1, a bottle cap 2, an air inlet pipe sleeve 3, an air outlet pipe sleeve 4, an air inlet pipe 5, an air outlet pipe 6, an air pump 7, a radon measuring instrument 8, a flowmeter 9 and a three-way electromagnetic valve 10.

An air inlet pipe sleeve 3 and an air outlet pipe sleeve 4 are respectively arranged on the bottle cap 2, an air inlet pipe 5 is inserted on the air inlet pipe sleeve 3, an air outlet pipe 6 is inserted on the air outlet pipe sleeve 4, the air outlet pipe 6 is connected with an air inlet end of an air pump 7 through a hose, an air outlet end of the air pump 7 is connected with an air inlet end of a three-way electromagnetic valve 10 through a hose, a first air outlet end of the three-way electromagnetic valve 10 is connected with an air inlet end of a radon measuring instrument 8 through a hose, a second air outlet end of the three-way electromagnetic valve 10 is communicated with the atmospheric environment, and an air outlet end of the radon measuring instrument 8 is connected with a flowmeter 9 through a hose.

The method for synchronously measuring the effective decay constant and the radium concentration in water in an open-loop manner by adopting the measuring device comprises a measuring process and a calculating process, and specifically comprises the following steps:

first, measurement process

A. Placing a device for synchronously measuring the effective decay constant and the radium concentration in water in an open-loop mode in a constant-temperature environment, and measuring the environment temperature;

B. pouring a water sample to be detected into the water sample measuring bottle 1, tightly covering the bottle cap 2, enabling the air outlet of the air inlet pipe 5 to be positioned in the water sample to be detected and close to the bottle bottom of the water sample measuring bottle 1, and enabling the air inlet of the air outlet pipe 6 to be positioned on the liquid level of the water sample to be detected;

C. opening a second air outlet end of the three-way electromagnetic valve 10, closing a first air outlet end of the three-way electromagnetic valve 10, starting the air pump 7, controlling the flow rate of the air pump 7, enabling air to enter sample water to be detected through the air inlet pipe 5 for bubbling, simultaneously carrying out radon in the sample water to be detected, entering the air pump 7 through the air outlet pipe 6 for entering the three-way electromagnetic valve 10, and then entering an atmospheric environment from the second air outlet end of the three-way electromagnetic valve 10, wherein the radon concentration in the air path can be considered to be 0 after the air pump 7 is started for 5-30 minutes due to the very high flow rate of the air pump 7;

D. closing the second air outlet end of the three-way electromagnetic valve 10, opening the first air outlet end of the three-way electromagnetic valve 10, controlling the air pump 7 to reduce the flow rate by acquiring the reading of the flowmeter 9, so that air enters the water sample to be detected through the air inlet pipe 5 to be bubbled, simultaneously carrying out radon in the water sample to be detected, enters the air pump 7 through the air outlet pipe 6 to enter the three-way electromagnetic valve 10, then enters the radon detector 8 from the first air outlet end of the three-way electromagnetic valve 10, and then enters the atmospheric environment through the flowmeter 9; when the flow rate of the air pump 7 is reduced, the flow rate of the air pump 7 is kept moderate, so that the radon concentration in the measuring cavity of the radon detector 8 and the gaseous radon concentration in the water sample measuring bottle 1 synchronously change.

Second, calculating process

And calculating the radium concentration in the water sample according to the environment temperature, the volume of the water sample to be detected, the flow rate of the air pump 7 and the reading of the radon measuring instrument 8.

Radon in the water sample to be detected comes from decay of radium in water, and the volume of the water sample to be detected is V, and the activity of the radium in water is A_RaAnd then the radium concentration in water is C_RaComprises the following steps:

C_Ra＝A_Ra/V (1)

radon concentration C 'in water'_RnThe change rule is as follows:

in the formula of lambda_RnIs the decay constant, C, of radon_RnThe concentration of the gaseous radon in the water sample measuring bottle is measured, L is the flow rate of the air pump 7, and lambda_lIs the leakage coefficient, V₁Is the volume of the gas path from the water sample measuring bottle 1 to the measuring cavity of the emanometer 8. Because the air pump 7 has a large flow rate, the gaseous radon concentration from the water sample measuring bottle 1 to the measuring cavity of the radon measuring instrument 8 can be considered to be the same.

According to the temperature during measurement, the concentration ratio X of water radon to gaseous radon during balance can be obtained by looking up a table, and the concentration ratio X comprises the following components:

C'_Rn＝XC_Rn (3)

substituting formula (3) for formula (2) to obtain:

order to

In the formula of_eIs the effective decay constant.

Equation (4) can be simplified as:

the solution of equation (6) is:

the measurement process adopts a short time interval measurement, namely one measurement in 2-10 minutes, and a plurality of periods are measured until the radon concentration tends to a constant value.

And (3) defining the radon concentration data of a plurality of measured periods as the radon concentration of the midpoint of the plurality of periods, and fitting nonlinear data by using a formula (7) to synchronously obtain the radium concentration and the effective decay constant in the water.

Claims (1)

1. The method for synchronously measuring the effective decay constant and the radium concentration in water in an open-loop manner is based on a device for synchronously measuring the effective decay constant and the radium concentration in water in an open-loop manner, and the device comprises a water sample measuring bottle, a bottle cap, an air inlet pipe sleeve, an air outlet pipe sleeve, an air inlet pipe, an air outlet pipe, an air pump, a radon measuring instrument, a flowmeter and a three-way electromagnetic valve;

the air inlet pipe sleeve and the air outlet pipe sleeve are respectively arranged on the bottle cap, the air inlet pipe is inserted into the air inlet pipe sleeve, the air outlet pipe is inserted into the air outlet pipe sleeve, the air outlet pipe is connected with the air inlet end of the air pump through a hose, the air outlet end of the air pump is connected with the air inlet end of the three-way electromagnetic valve through a hose, the first air outlet end of the three-way electromagnetic valve is connected with the air inlet end of the radon detector through a hose, the second air outlet end of the three-way electromagnetic valve is communicated with the atmospheric environment, and the air outlet end of the radon detector is connected with the flowmeter through a hose;

the method is characterized by comprising a measuring process and a calculating process, and the method comprises the following specific steps:

first, measurement process

A. Placing a device for synchronously measuring the effective decay constant and the radium concentration in water in an open-loop mode in a constant-temperature environment, and measuring the environment temperature;

B. pouring a water sample to be detected into the water sample measuring bottle, tightly covering the bottle cap, wherein the air outlet of the air inlet pipe is positioned in the water sample to be detected and close to the bottle bottom of the water sample measuring bottle, and the air inlet of the air outlet pipe is positioned on the liquid level of the water sample to be detected;

C. opening a second air outlet end of the three-way electromagnetic valve, closing a first air outlet end of the three-way electromagnetic valve, starting the air pump, controlling the flow rate of the air pump, enabling air to enter a water sample to be tested for bubbling through the air inlet pipe, simultaneously carrying out radon in the water sample to be tested, entering the three-way electromagnetic valve through the air outlet pipe, and then entering an atmospheric environment from the second air outlet end of the three-way electromagnetic valve, wherein the radon concentration in the air path can be considered to be 0 after the air pump is started for 5-30 minutes due to the very large flow rate of the air pump;

D. closing a second air outlet end of the three-way electromagnetic valve, opening a first air outlet end of the three-way electromagnetic valve, controlling the air pump to regulate the flow rate to be small by acquiring the reading of the flow meter, so that air enters the water sample to be tested through the air inlet pipe to bubble, simultaneously carrying out radon in the water sample to be tested, enters the three-way electromagnetic valve through the air outlet pipe, enters the radon detector from the first air outlet end of the three-way electromagnetic valve, and then enters the atmospheric environment through the flow meter; when the flow rate of the air pump is reduced, the flow rate of the air pump is kept moderate, so that the radon concentration in the measuring cavity of the radon measuring instrument and the gaseous radon concentration in the water sample measuring bottle synchronously change;

second, calculating process

Calculating radium concentration in the water sample according to the environment temperature, the volume of the water sample to be detected, the flow rate of the air pump and the reading of the radon measuring instrument;

radon in the water sample to be detected comes from decay of radium in water, and the volume of the water sample to be detected is V, and the activity of the radium in water is A_RaAnd then the radium concentration in water is C_RaComprises the following steps:

C_Ra＝A_Ra/V (1)

radon concentration C 'in water'_RnThe change rule is as follows:

in the formula of_RnIs the decay constant, C, of radon_RnThe concentration of the gaseous radon in the water sample measuring bottle is measured, L is the flow rate of the air pump, and lambda is_lIs the leakage coefficient, V₁The volume of the gas path from the water sample measuring bottle to the measuring cavity of the radon measuring instrument is large, and the gas radon concentration from the water sample measuring bottle to the measuring cavity of the radon measuring instrument can be considered to be the same due to the large flow rate of the air pump;

according to the temperature during measurement, the concentration ratio X of water radon to gaseous radon during balance can be obtained by looking up a table, and the concentration ratio X comprises the following components:

C'_Rn＝XC_Rn (3)

substituting formula (3) into formula (2) to obtain:

order to

In the formula of lambda_eIs the effective decay constant;

equation (4) can be simplified as:

the solution of equation (6) is:

the measurement process adopts short time interval measurement, namely measurement is carried out once in 2-10 minutes, and a plurality of periods are measured until the radon concentration tends to a constant value;

and (3) defining the radon concentration data of a plurality of measured periods as the radon concentration of the midpoint of the plurality of periods, and fitting nonlinear data by using a formula (7) to synchronously obtain the radium concentration and the effective decay constant in the water.

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