KR102375360B1 - a differential pressure type flowmeter with safely fixed temperature sensor - Google Patents

Abstract

The present invention is a differential pressure flow meter, and it has a temperature sensor of a safe structure to prevent the sensor wire from being caught or externally damaged. In addition, the existing differential pressure flow meter measures the differential pressure and pressure with each sensor to calculate the flow rate, or a pressure vessel. In order to measure the internal water level, the present invention cannot measure the differential pressure and pressure simultaneously with one sensor, so cost reduction is difficult and space utilization is limited. On the other hand, a temperature sensor with a safe structure and pressure to simultaneously measure pressure and differential pressure It relates to a differential pressure flow meter having an integrated sensor.
The present invention is configured to include a venturi tube 100, a pressure integrated sensor 200, and a temperature sensor unit 300,
The venturi tube 100 is configured to include an upper tube 110 and a lower tube 120,
The pressure integrated sensor 200 is configured to include a high pressure sensor unit 210, a low pressure sensor unit 220, a calculation unit 230, and an output unit 240,
The temperature sensor unit 300 includes a temperature sensor 310 and a sensor wire 320,
The temperature sensor 310 is located in the upper tube 110 of the venturi tube 100 and is located between the high pressure sensor unit 210 and the low pressure sensor unit 220. A temperature sensor of a safe structure and To provide a differential pressure flow meter having a pressure-integrated sensor capable of simultaneously measuring pressure and differential pressure and measuring flow.
In the present invention, the sensor wire 320 is connected to the temperature sensor 310 and the calculation unit 230, and is located between the high pressure sensor unit 210 and the low pressure sensor unit 220. Provided is a differential pressure flowmeter having a temperature sensor of a structure and a pressure-integrated sensor capable of simultaneously measuring pressure and differential pressure and measuring flow.
In addition, in the present invention, a communication unit 250 is added to the pressure integrated sensor 200 so that it is connected to a wired or wireless communication device and transmits pressure information, flow rate information, water level information, etc. A temperature sensor with a safe structure that can measure pressure and differential pressure at the same time and measure flow or water level, characterized in that it can perform the function of receiving information, and a pressure-integrated pressure sensor that simultaneously measures pressure and differential pressure and measures the flow rate A differential pressure flow meter having a sensor is provided.

Description

A differential pressure type flowmeter with safely fixed temperature sensor

The present invention is a differential pressure flow meter, and it has a temperature sensor of a safe structure to prevent jamming or external damage to the sensor wire. In addition, the existing differential pressure flow meter measures the differential pressure and pressure with each sensor to calculate the flow rate, or to use a pressure vessel. In order to measure the internal water level, the present invention cannot measure the differential pressure and pressure at the same time with one sensor, so cost reduction is difficult and space utilization is limited. On the other hand, a temperature sensor with a safe structure and pressure to measure pressure and differential pressure at the same time It relates to a differential pressure flow meter having an integrated sensor.

The differential pressure flow meter refers to a differential pressure mechanism that generates a pressure difference before and after the flow according to the flow rate when the fluid passes and measures the flow rate using the pressure difference.

Such differential pressure flowmeters include an orifice type, venturi type, wedge type, etc. The double wedge type differential pressure flowmeter cuts one side of the connecting pipe in a V shape and cuts a V By welding and installing a ruler-shaped wedge, a differential pressure is generated in the front and rear of the fluid flow, and the differential pressure is taken out and the flow rate is measured with a differential pressure gauge.

Conventionally, in semiconductor manufacturing facilities and chemical plants, mass flow type flow meters (thermal mass flow meters), etc. A flow meter has been widely used.

However, thermal mass flow meters have low responsiveness, low measurement accuracy in the low flow rate region, many operating troubles, restrictions on the type of controlled gas, and the influence of pressure fluctuations. There are many difficulties, such as the point that it is easy to receive.

Similarly, real-time flow measurement or flow control is difficult with a build-up type flow meter, cannot be used in-line, there is a restriction on the pressure of the controlled gas, and a separate line is required for measurement. There are problems such as

On the other hand, a differential pressure flow meter using an orifice and a pressure gauge has almost no restrictions depending on the type of gas to be controlled, can be used in-line, and has excellent utility in that real-time flow measurement or flow control is performed. will be

Such a differential pressure flow meter uses Bernoulli's law, and when a part of the pipe through which the fluid flows is reduced, the speed increases and the pressure decreases when the fluid passes through that part, so that there is a difference between the front and rear pressure difference of the pipe and the flow rate. A certain relationship is established, and this differential pressure is converted into a measured flow rate.

As a related technology, Registered Patent No. 10-1568297 (a differential pressure flow meter that is easy to manufacture and install, hereinafter referred to as the prior art) states, "(a) a first pipe and a second pipe each having a compression connection means on the surfaces facing each other; (b) is placed between the opposing compression connection means of the first pipe and the second pipe and is installed by being pressed between the first pipe and the second pipe when the first pipe and the second pipe are crimped connected, (b1) the first and the first pipe A plate member having an opening communicating with the second pipe, and (b2) a differential pressure member installed on the plate member to generate a differential pressure in the fluid flowing through the first pipe, the opening of the plate member, and the second pipe a forming plate; having a first pipe pressure detecting hole for and a second pipe pressure detecting hole for detecting the pressure on the second pipe side, (e) the first pressure outlet is installed to communicate with the first pipe pressure detecting hole in the plate member and the second pressure outlet is a differential pressure flow meter, characterized in that it is installed to communicate with the second pipe pressure detecting hole in the plate member.

However, the differential pressure flowmeter of the prior art and the prior art measures the differential pressure and pressure with each sensor to calculate the flow rate or measure the water level in the pressure vessel. There are disadvantages in that cost reduction is difficult and space utilization is limited.

In addition, the differential pressure flow meter of the prior art and the prior art calculates the flow rate by measuring the differential pressure, pressure, and temperature with each sensor. In particular, since the temperature sensor is located outside the differential pressure measurement area, the It has the disadvantage of having continuous field problems because it can be damaged during installation.

Differential pressure flowmeters of the prior art and prior art measure the differential pressure, pressure, and temperature with each sensor to calculate the flow. There is a disadvantage of having a continuous on-site problem because the present invention solves this problem, and the present invention improves a safe structure and durability, as well as a temperature sensor of a safe structure that can give a beautiful appearance, and a temperature sensor that measures pressure and differential pressure at the same time. An object of the present invention is to provide a differential pressure flow meter having a pressure integrated sensor.

In the present invention, the differential pressure flow meter of the prior art and the prior art measures the differential pressure and the pressure with each sensor to calculate the flow rate or measure the water level in the pressure vessel, and one sensor can simultaneously measure the differential pressure and pressure It is an improvement on the disadvantages of having difficulty in reducing costs and having restrictions on space utilization because there is no

The improved pressure and differential pressure sensor uses two pressure sensors as an integrated pressure sensor, and by utilizing the high pressure side of the differential pressure as pressure (absolute pressure, gauge pressure), it is possible to measure pressure and differential pressure without installing a separate pressure sensor. An object of the present invention is to provide a differential pressure flowmeter having a temperature sensor of a safe structure and a pressure integrated sensor that simultaneously measures pressure and differential pressure for the purpose of reducing costs.

The present invention in order to solve the above problems and needs,

Doedoe configured to include a venturi tube 100, a pressure integrated sensor 200, and a temperature sensor unit 300,

The venturi tube 100 is configured to include an upper tube 110 and a lower tube 120,

The pressure integrated sensor 200 is configured to include a high pressure sensor unit 210, a low pressure sensor unit 220, a calculation unit 230, and an output unit 240,

The temperature sensor unit 300 includes a temperature sensor 310 and a sensor wire 320,

The temperature sensor 310 is located in the upper tube 110 of the venturi tube 100 and is located between the high pressure sensor unit 210 and the low pressure sensor unit 220. A temperature sensor of a safe structure and To provide a differential pressure flow meter having a pressure-integrated sensor capable of simultaneously measuring pressure and differential pressure and measuring flow.

In the present invention, the sensor wire 320 is connected to the temperature sensor 310 and the calculation unit 230, and is located between the high pressure sensor unit 210 and the low pressure sensor unit 220. Provided is a differential pressure flowmeter having a temperature sensor of a structure and a pressure-integrated sensor capable of simultaneously measuring pressure and differential pressure and measuring flow.

In addition, in the present invention, a communication unit 250 is added to the pressure integrated sensor 200 to be connected to a wired/wireless communication device, transmit pressure information, flow rate information, water level information, etc., and update the calculation program mounted on the calculation unit. A temperature sensor with a safe structure that can measure pressure and differential pressure at the same time and measure flow or water level, characterized in that it can perform the function of receiving information, and a pressure-integrated pressure sensor that simultaneously measures pressure and differential pressure and measures flow A differential pressure flow meter having a sensor is provided.

The differential pressure flowmeter of the prior art and the prior art calculates the flow rate by measuring the differential pressure, pressure, and temperature with each sensor. As a result, there was a disadvantage that there was a continuous field problem. The differential pressure flow meter having a temperature sensor of a safe structure and a pressure integrated sensor that simultaneously measures pressure and differential pressure according to the present invention completely solves these problems, It not only improves the safe structure and durability, but also has the effect of giving the appearance of beauty,

In addition, since a pressure guiding pipe for measuring the differential pressure is installed at the front and rear ends of the tightening mechanism (Venturi pipe, etc.) and a temperature sensor is installed between them, it is possible to prevent the installation of a flow meter or damage to the sensor wire due to unexpected external force. It has the effect of preventing errors and increasing durability.

In addition, the conventional and prior art differential pressure flowmeters measure the differential pressure and pressure with each sensor to calculate the flow rate or measure the water level in the pressure vessel. On the other hand, it has the disadvantage of being difficult and limited in the use of space.

The differential pressure flow meter according to the present invention has a pressure integrated sensor, which uses two pressure sensors and utilizes the high pressure side of the differential pressure as pressure (absolute pressure, gauge pressure), so that a separate pressure sensor is not installed. It is a structure that can measure pressure, flow rate, or water level because it can measure the differential pressure, so the instrument is simple and the cost is significantly reduced.

1 is a conventional differential pressure flow meter structure.
2 is a structure of a differential pressure type flow meter having a temperature sensor having a safe structure and a pressure integrated sensor for simultaneously measuring pressure and differential pressure according to the present invention.
3 is a structure of a pressure-integrated sensor of a differential pressure type flowmeter having a temperature sensor having a safe structure and a pressure-integrated sensor for simultaneously measuring pressure and differential pressure according to the present invention.
Figure 3b is a calibration curve for the relationship between the pressure and voltage of the fluid acting in the high-pressure sensor unit of the pressure integrated sensor according to the present invention.
Figure 3c is a calibration curve for the relationship between the pressure and voltage of the fluid acting in the low pressure sensor unit of the pressure integrated sensor according to the present invention.
4 is an embodiment of a differential pressure flow meter having a temperature sensor having a safe structure and a pressure-integrated sensor for simultaneously measuring pressure and differential pressure according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

The present invention includes a temperature sensor having a safe structure including a venturi tube 100, a pressure integrated sensor 200, and a temperature sensor unit 300, and a pressure integrated sensor capable of simultaneously measuring pressure and differential pressure and measuring flow A differential pressure flow meter is provided.

Since the temperature sensor unit is installed between the high pressure sensor unit 210 and the low pressure sensor unit 220 in the temperature sensor unit 300 of the present invention, when a differential pressure type flow meter is installed or installed, unexpected external force Its technical feature is that it can prevent damage to the temperature sensor and sensor wire, enabling stable temperature measurement, and preventing errors in the flow meter by accurately compensating for the temperature of the fluid flow rate.

In addition, the pressure integrated sensor 200 of the present invention has a structure to be mounted on the venturi tube 100, and the technical feature is that it has a function of simultaneously measuring the pressure and the differential pressure of the fluid.

In addition, the present invention can be applied to both a conventional differential pressure flow meter and/or a differential pressure flow meter having a function to simultaneously measure the pressure and differential pressure of the fluid described above, and stable temperature measurement is possible by the temperature of the fluid flow rate. Its technical feature is that it acts to prevent errors in the flowmeter by providing accurate compensation.

As shown in FIG. 1, the conventional differential pressure flowmeter is equipped with a pressure sensor 201 and a differential pressure sensor 202 in the venturi tube 100, and each sensor measures the differential pressure and pressure to calculate the flow rate or measure the water level in the pressure vessel. got to measure

Therefore, since it is impossible to measure the differential pressure and the pressure at the same time with a single sensor, the cost is difficult and space utilization is limited.

As shown in FIG. 1 , the pressure sensor 201 is connected to the upper pipe 110 of the venturi pipe 100 and functions to measure the gauge pressure of a fluid (mainly liquid) passing through the venturi pipe.

The differential pressure sensor 202 is an upper pressure gauge 202-1 connected to the upper tube 110 of the venturi tube 100, and a lower pressure gauge 202 connected to the lower tube 120 of the venturi tube 100. -2) and consists of a differential pressure part 202-3 that measures and transmits the pressure difference (differential pressure) between the upper pressure gauge 202-1 and the lower pressure gauge 202-2, and the pressure of the upper and lower parts of the venturi tube It consists in measuring the car.

Therefore, (Equation 1) to calculate the flow rate is as follows.

(Equation 1)

where, Q: flow rate,

A1 : Area of upper pipe of Venturi pipe

A2 : Area of lower pipe of Venturi pipe

γ : specific weight of the fluid

g: gravitational acceleration

△p : pressure difference (differential pressure) between the upper and lower parts of the venturi tube (p1-p2)

(p1: upper pipe pressure of venturi pipe, p2: lower pipe pressure of venturi pipe)

is defined as

Therefore, in the conventional differential pressure flow meter, the pressure sensor 201 and the differential pressure sensor 202 had to be separately provided to measure the flow rate Q and the absolute pressure P (or gauge pressure) in the pipe.

As shown in FIG. 1, the conventional differential pressure flowmeter measures the temperature by mounting a temperature sensor to correct the volume change according to the temperature of the fluid, and then calculates the specific weight of the fluid according to the temperature to accurately measure the mass or volume of the fluid. will do

However, in such a conventional differential pressure flow meter, in particular, since the temperature sensor is located outside the differential pressure measurement area, it may be damaged during installation due to the sensor wire jamming or the protrusion of the exterior, or safety and damage problems may occur, thereby solving continuous on-site problems. Have,

In addition, the conventional differential pressure flowmeter having such a structure has a problem in that the user does not recognize it even if there is a jamming or damage to the sensor wire, so that the accurate flow rate of the fluid cannot be measured.

Therefore, the present invention is a technical feature of improving the structure of the wrong temperature sensor of the conventional differential pressure flowmeter, and installing an inlet pipe for measuring the differential pressure at the front and rear ends of the tightening mechanism and installing a temperature sensor therebetween As a feature of the structure, it has a function to prevent damage to the sensor wire due to unexpected external force when installing the flowmeter or after installation, thereby preventing errors of the flowmeter and significantly improving durability.

In the present invention, the differential pressure flow meter of the prior art and the prior art measures the differential pressure and the pressure with each sensor to calculate the flow rate or measure the water level in the pressure vessel. As it is an improvement of the disadvantages of having difficulty in cost reduction and restrictions on space utilization,

The improved pressure and differential pressure sensor uses two pressure sensors, and by utilizing the high pressure side of the differential pressure as pressure (absolute pressure, gauge pressure), it is a structure that can measure pressure and differential pressure without installing a separate pressure sensor. It is intended to provide a differential pressure flow meter for the purpose of implementing cost reduction.

The above-described venturi tube 100 of the present invention is configured to include an upper tube 110 and a lower tube 120 .

As shown in FIG. 2 , the upper pipe 110 refers to a pipe through which a fluid flows.

The cross-sectional area of the upper pipe 110 is represented by A1.

The lower pipe 120 has a smaller cross-sectional area than the upper pipe 110 and means a pipe through which the fluid flows out, and the cross-sectional area of the lower pipe is expressed as A2.

A tightening mechanism portion 101 is configured between the upper tube 110 and the lower tube 120 . As the fluid passes through the tightening mechanism portion 101 , the flow rate increases and the pressure changes.

The tightening mechanism 101 has a fluid passage portion 102 having a size smaller than the diameter of the upper pipe to change the flow velocity and pressure of the fluid, and may be composed of an orifice or the like.

In general, the cross-sectional area of the upper tube of the venturi tube is formed to be larger than the cross-sectional area of the lower tube, so that the flow velocity in the lower tube is greater than the flow velocity in the upper tube.

The pressure integrated sensor 200 of the present invention is configured to include a high pressure sensor unit 210 , a low pressure sensor unit 220 , an operation unit 230 , and an output unit 240 .

The high-pressure sensor unit 210 of the present invention means a device or means for measuring the normal absolute pressure and providing the measured pressure information to the operation unit.

Therefore, the high pressure sensor unit 210 is equipped with a general pressure measuring sensor 211 or a pressure measuring gauge.

Preferably, the high-pressure sensor unit 210 of the present invention has a pressure sensor that senses the pressure of the fluid by a pressure sensor element such as a membrane and generates a change in voltage according to the degree of pressure measured by the pressure sensor element. It is better to have the equipment provided.

As shown in FIG. 3 , the high pressure sensor unit 210 includes a pressure measuring sensor 211 and a filter converter 212 .

The pressure measuring sensor 211 means a sensor that senses the pressure of a fluid by a pressure sensor element such as a membrane and a change in voltage occurs according to the pressure level measured by the pressure sensor element.

The filter converter 212 includes an analog digital converter (ADC), and removes noise by passing a voltage signal detected by the pressure measurement sensor and output through a LOW PASS FILTER, and an analog-digital converter (ADC) It means a device or means for performing a function of limiting current for stability and transmitting a voltage signal to the above-described operation unit.

The low pressure sensor unit 220 of the present invention includes a low pressure pressure measuring sensor 221 and a low pressure filter converter 222 .

The low-pressure pressure measuring sensor 221 means a sensor that senses the pressure of a fluid by a pressure sensor element such as a membrane and a change in voltage occurs according to the degree of pressure measured by the pressure sensor element.

The low-pressure filter converter 222 includes an analog digital converter (ADC), and removes noise by passing a voltage signal detected by the pressure measurement sensor and output through a LOW PASS FILTER, and an analog-digital converter (ADC). ) means a device or means that performs a function of limiting current for stability and transmitting a voltage signal to the above-described operation unit.

The operation unit 230 of the present invention is provided with a CPU, a micro controller unit (MCU), a RAM or ROM, a memory, and the like, and means a device or means capable of driving software such as a computer program or an application program.

The operation unit 230 uses the high-pressure voltage signal (hv) provided by the high-pressure sensor unit and the low-pressure voltage signal (lv) provided by the low-pressure sensor unit to measure the fluid pressure P1 and the low pressure by the high-pressure sensor unit. It performs a function of calculating the fluid pressure (P2) measured by the sensor unit.

As shown in FIGS. 3B and 3C , the calculation unit prepares a calibration curve for the relationship between the pressure and voltage of the fluid acting in the high-pressure sensor unit and the low-pressure sensor unit in advance, and arranges them as data.

Then, the high-pressure voltage signal and the low-pressure voltage signal measured by the high-pressure sensor unit and the low-pressure sensor unit correspond to the calibration curve to measure the pressure of the fluid.

That is, the formula for calculating the fluid pressure (P1) measured by the high pressure sensor unit and the fluid pressure (P2) measured by the low pressure sensor unit is as follows.

Fluid pressure (P1) = a(hv) + b ---- (Equation 2)

where a: slope (constant) of the calibration curve of the high-pressure sensor part

b: intercept (constant)

Fluid pressure of the low pressure sensor part (P2) = c(lv) + d ----- (Equation 3)

where c: slope (constant) of the calibration curve of the low pressure sensor unit

d: intercept (constant)

In the present invention, the fluid pressure P1 of the high pressure sensor unit obtained above means the fluid pressure of the upper pipe 110 of the venturi pipe 100, and the fluid pressure P2 of the low pressure sensor unit is the lower pipe of the venturi pipe 100 (120) means the fluid pressure.

In the present invention, it is possible to measure the flow rate of the fluid by the following calculation formula in the above calculation unit.

(Equation 4)

where Q: flow rate (m ³ /h, L/m)

A1 : Area of upper pipe of Venturi pipe

A2 : Area of lower pipe of Venturi pipe

γ : specific weight of the fluid

g: gravitational acceleration

p1 : upper pipe pressure of venturi pipe

p2 : lower pipe pressure of venturi pipe

is defined as

That is, by substituting the fluid pressure P1 of the high pressure sensor unit and the fluid pressure P2 of the low pressure sensor unit measured by the calculation unit into the above (Equation 4), the flow rate of the fluid can be easily calculated.

Each of the above coefficients A1, A2, γ, g, etc. is already input as data to the calculation unit according to the type of fluid, so that when the type of fluid is selected, it is automatically entered into the above calculation formula.

The present invention can measure the pressure (P1) of the fluid with one configuration described above, and also measure the flow rate (Q) of the fluid at once.

Therefore, in the present invention, since the differential pressure and pressure P1 are simultaneously measured and used with two pressure sensors (high pressure sensor unit and low pressure sensor unit) as described above, the differential pressure value from the pressure sensor without installing each pressure sensor and differential pressure sensor Because it receives an overpressure value, there is no need for a separate sensor and installation cost compared to the existing system, and it is possible to maintain the form of a differential pressure flowmeter with a simple structure, and the effect of simultaneously measuring the pressure in the pressure vessel is shown.

As shown in FIG. 2, the present invention adds a temperature sensor unit 300 capable of measuring the temperature of the fluid, measures the temperature of the fluid, and provides the function to the operation unit 230, and the output unit 240 ) to display the temperature of the fluid.

As described above, as shown in FIG. 1, the conventional differential pressure flowmeter is equipped with a temperature sensor to correct the volume change according to the temperature of the fluid, measures the temperature, and calculates the specific weight of the fluid according to the temperature to obtain an accurate flow rate of the fluid. to measure mass or volume.

However, in such a conventional differential pressure flow meter, in particular, since the temperature sensor is located outside the differential pressure measurement area, it may be damaged during installation due to the sensor wire jamming or the protrusion of the exterior, or safety and damage problems may occur, thereby solving continuous on-site problems. Have,

In addition, the conventional differential pressure flowmeter having such a structure has a problem in that the user does not recognize it even if there is a jamming or damage to the sensor wire, so that the accurate flow rate of the fluid cannot be measured.

Therefore, the present invention is a technical feature of improving the structure of the wrong temperature sensor of the conventional differential pressure flowmeter, and installing an inlet pipe for measuring the differential pressure at the front and rear ends of the tightening mechanism and installing a temperature sensor therebetween As a feature of the structure, it has a function to prevent damage to the sensor wire due to unexpected external force when installing the flowmeter or after installation, thereby preventing errors of the flowmeter and significantly improving durability.

The temperature sensor unit 300 of the present invention includes a temperature sensor 310 and a sensor wire 320 .

The temperature sensor 310 of the present invention means a device or means for measuring the temperature of the fluid inside the differential pressure flowmeter.

The sensor wire 320 of the present invention is connected to the temperature sensor 310 and the pressure integrated sensor 200 and performs a function of providing the temperature of the fluid measured by the temperature sensor 310 to the operation unit 230 . will do

As shown in FIG. 2 , the temperature sensor 310 of the present invention is located in the upper pipe 110 of the venturi pipe 100 , and is located between the high pressure sensor unit 210 and the low pressure sensor unit 220 . characterized.

In particular, the temperature sensor 310 is preferably installed above the upper tube 110 of the venturi tube 100, is located below the operation unit 230 of the pressure integrated sensor 200, and is located between the upper tube and the lower tube. It is preferable to be located at 1/3 to 1/5 of the diameter of the upper pipe (A1) in the direction of the upper pipe from the front part (F) of the tightening mechanism part 101 in the upper pipe, preferably 1/ of the diameter of the upper pipe (A1) It is better to be located within the range of 10% at the distance of 4, and more preferably located at 1/4 of the diameter of the upper pipe (A1) has the effect of increasing the temperature response efficiency.

In addition, the high-pressure sensor unit 210 of the present invention is preferably installed in the upper pipe 110, from the front part (F) of the tightening mechanism 101 to the upper pipe direction 3/4 to 5 of the upper pipe diameter (A1) It is preferably located at /4, preferably located within a range of 10% at a distance of 4/4 (=1) of the diameter of the upper pipe (A1), more preferably within the range of 10% of the diameter of the upper pipe (A1) ) at 4/4 (=1) shows good response efficiency for sensing the pressure of the upper pipe.

In addition, the low pressure sensor unit 210 of the present invention is preferably installed in the lower pipe 120, 1/3 to 3 of the diameter of the upper pipe (A1) from the front part (F) of the tightening mechanism 101 to the lower pipe direction It is preferably located at /4, preferably located within a range of 10% at a distance of 1/2 of the diameter of the upper pipe A1, more preferably 1/ of the diameter of the upper pipe A1 Positioning at 2 shows good response efficiency for sensing the pressure of the lower pipe.

In addition, the sensor wire 320 of the present invention is also connected to the temperature sensor 310 and the calculating unit 230 and is characterized in that it is positioned between the high pressure sensor unit 210 and the low pressure sensor unit 220 .

In the case of the prior art, since the temperature sensor is located outside the differential pressure measurement area, it may be damaged during installation due to the jamming of the sensor wire or the protrusion of the exterior. 300), the temperature sensor and the sensor wire are located below the calculation unit 230 and are located between the high-pressure sensor unit 210 and the low-pressure sensor unit 220, so that the temperature sensor is not protruding to the outside and has a safe structure. The sensor unit is formed to solve the problems of the prior art, as well as to increase durability and to give an aesthetic appearance.

In addition, since the temperature sensor unit is installed between the high pressure sensor unit 210 and the low pressure sensor unit 220, damage to the temperature sensor and sensor wire due to unexpected external force can be prevented even when a differential pressure flow meter is installed or installed. Stable temperature measurement is possible and accurate compensation is made by the temperature of the fluid flow to prevent errors in the flowmeter.

In addition, in the present invention, when the above-described fluid is a gas whose volume changes according to temperature, the specific weight (γ ₁ ) of the above-described gas is obtained by the following arithmetic formula (Equation 5).

(Equation 5)

γ ₁ =

here,

γ ₁ : specific weight at the temperature of the measured fluid,

γ: specific weight in the reference state,

n: reference state,

P1: pressure at the measured fluid temperature

Pn: absolute pressure in the reference state,

Tn: absolute temperature of the reference state (273.15+℃),

T1 : Measured temperature of the fluid (absolute temperature),

am.

(The reference state here means the values for the pressure, specific weight, and temperature measured at a specific temperature of the gas to be measured and is preset)

In this way, the present invention measures the temperature of the fluid and measures the specific weight accordingly to calculate the flow rate of the fluid by substituting it into the stretching formula (Equation 4) to calculate the fluid even if the volume and density of the fluid change according to the temperature. The effect that can be measured more accurately appears.

The output unit 240 of the present invention means a device or means to output and display the pressure (P1), the differential pressure (Δp), and/or the flow rate (Q) derived from the above-described operation unit, and is generally composed of a monitor or the like. can

In the present invention, a communication unit 250 can be added, so that it is connected to a wired or wireless communication device through the communication unit 250 and also transmits pressure information, flow rate information, water level information, etc., and updates the calculation program mounted on the calculation unit. It can perform the function of receiving information so that

When the differential pressure flow meter of the present invention is mounted on a fluid to be measured by an application installed on a smartphone by the communication unit 250, the pressure, flow rate, water level, etc. of the fluid can be easily recognized with a smartphone. effect will appear.

The above-described configuration of the pressure integrated sensor 200 of the present invention is included in a case, and the case is preferably made of a polymer material to protect the internal configuration.

The above-mentioned polymer material resin is polyethylene (PE), polyethylene terephthalate (PET, polyethylene terephthalate)), polypropylene (PP), sulfonated polystyrene (SPS, sulfonated polystyrene), OPP (Oriented Poly Propylene), CPE ( Chlorinated Polyethylene), EVA (Ethylene Vinyl Acetate), methyl methacrylate-butadiene-styrene (MBS) resin, and acrylonitrile-butadiene-styrene (ABS) resin are mixed.

The above-mentioned polymeric resin is polyethylene (PE) 100 parts by weight, polyethylene polyethylene terephthalate (PET, polyethylene terephthalate) 20-50 parts by weight, polypropylene (PP) 20-50 parts by weight, sulfonated polystyrene (SPS, sulfonated polystyrene) ) 20-50 parts by weight, OPP (Oriented Poly Propylene) 20-50 parts by weight, CPE (Chlorinated Polyethylene) 1-2 parts by weight, EVA (Ethylene Vinyl Acetate) 1-2 parts by weight, methyl methacrylate- 0.5 to 1 parts by weight of butadiene-styrene (MBS) resin and 0.5 to 1 parts by weight of acrylonitrile-butadiene-styrene (ABS) resin are mixed.

The case made of the above-described polymeric resin of the present invention exhibits remarkably good technical characteristics in acid resistance, base resistance and corrosion resistance.

The present invention has a technical feature in that a flame retardant additive is added to the above-described polymeric resin.

The above-described flame-retardant additive has technical characteristics in that it is a composition in which aluminum hydroxide, phosphoric acid, acetic acid, graphite, and zinc oxide are mixed.

When measuring gaseous fluids, the flame retardant additive performs a function that enables the differential pressure flowmeter of the present invention to perform very stable measurements when measuring gaseous fluids vulnerable to heat.

It is very effective to mix the flame retardant additive with 100 parts by weight of aluminum hydroxide 5 to 10 parts by weight of phosphoric acid, 5 to 10 parts by weight of acetic acid, 2 to 5 parts by weight of graphite, and 1 to 2 parts by weight of zinc oxide.

The present invention may be used by mixing 0.1 to 5 parts by weight of the flame retardant additive based on 100 parts by weight of the polyethylene.

The above-mentioned aluminum hydroxide has a characteristic of emitting crystal water when heated by a flame, etc., and thus acts to improve flame retardancy.

Aluminum hydroxide has the formula Al(OH)3, specific gravity of about 2.423, and is an amphoteric hydroxide of aluminum.

Zinc oxide is called zinc oxide as industrial drugs, pharmaceuticals, and pigments. When used as a white pigment, it is called zinc white. It is a light white powder with melting points of 1,975°C (pressurized) and 1,720°C (normal pressure), and specific gravity of 5.47 (amorphous) and 5.78 (crystalline). It turns yellow when heated to about 300°C, but returns to its original color when cooled. It is almost insoluble in water, but is an amphoteric oxide soluble in dilute acids and concentrated alkalis. In the present invention, it is mixed with other additives to improve the flame retardancy.

The present invention has a technical feature in that the case is manufactured by using a polymeric resin having significantly improved strength and durability by mixing a natural reinforcing composition with the above-described polymeric resin.

When the above-described natural reinforcing composition is mixed, the strength of the case is increased, as well as the electrostatic action acting on the case is minimized, thereby remarkably reducing the occurrence of electrostatic errors in the differential pressure flowmeter.

In the present invention, it is preferable to mix 0.5 to 1.5 parts by weight of the natural reinforcing composition based on 100 parts by weight of the polyethylene.

The above-described natural strengthening composition of the present invention refers to a composition extracted by mixing Baekbokryeong, Geumgeumhwa, Peony, White paper, Gosam, Gyomaek, and Baekseonpi.

The natural strengthening composition described above is 100 parts by weight of Baekbokryeong, 50 to 150 parts by weight of gold and silver coins, 50 to 150 parts by weight of earl, 50 to 150 parts by weight of white paper, 50 to 150 parts by weight of ginseng, 50 to 150 parts by weight of gyomaek, 50 to 50 parts by weight of white sage It is preferable to extract the raw material mixed with 150 parts by weight.

As a method of extracting the natural reinforcing composition, 800-1000 parts by weight of 70-85% [mass %] ethanol is added to 100 parts by weight of the mixed raw materials, extracted under reflux for 2-4 hours, and the filtrate is removed using a rotary evaporator. It can be extracted by a method of reduced pressure and concentration, and about 80 to 150 parts by weight of an extract can be obtained.

The natural fortifying composition described above may be extracted as a powder, and such powder may be added.

The present invention provides a differential pressure type flowmeter having a temperature sensor having a safe structure and a pressure integrated sensor for simultaneously measuring pressure and differential pressure having the above-described configuration and functions.

The present invention is very useful in industries that produce, manufacture, sell, distribute, and research differential pressure flow meters.

In particular, the present invention can be used by simultaneously measuring the differential pressure and pressure P1 with two pressure sensors (high pressure sensor unit, low pressure sensor unit), and a temperature sensor with a safe structure to which a stable and safe temperature sensor unit is added, and pressure and differential pressure at the same time It is very useful in industries that produce, manufacture, sell, distribute, and research differential pressure flow meters equipped with integrated pressure sensors.

Venturi tube (100),
Upper pipe 110, lower pipe 120,
pressure integrated sensor 200,
High pressure sensor unit 210, low pressure sensor unit 220, calculating unit 230, output unit 240,
communication unit 250,
Temperature sensor unit 300, temperature sensor 310, sensor wire 320

Claims (3)

Doedoe configured to include a venturi tube 100, a pressure integrated sensor 200, and a temperature sensor unit 300,
The venturi tube 100 is configured to include an upper tube 110 and a lower tube 120,
The pressure integrated sensor 200 is configured to include a high pressure sensor unit 210, a low pressure sensor unit 220, a calculation unit 230, and an output unit 240,
The temperature sensor unit 300 includes a temperature sensor 310 and a sensor wire 320,
The temperature sensor 310 is located in the upper tube 110 of the venturi tube 100 and is located between the high pressure sensor unit 210 and the low pressure sensor unit 220,
The temperature sensor 310 is located at 1/3 to 1/5 of the diameter of the upper pipe (A1) from the front part (F) of the tightening mechanism part 101 between the upper pipe and the lower pipe in the direction of the upper pipe,
The sensor wire 320 is connected to the temperature sensor 310 and the calculation unit 230, and is located between the high pressure sensor unit 210 and the low pressure sensor unit 220,
The high-pressure sensor unit 210 is installed in the upper pipe 110 and is located at 3/4 to 5/4 of the upper pipe diameter A1 from the front part F of the tightening mechanism 101 to the upper pipe direction,
The low pressure sensor unit 220 is installed in the lower pipe 120 and located at 1/3 to 3/4 of the diameter of the upper pipe (A1) from the front part (F) of the tightening mechanism part 101 to the lower pipe direction. A differential pressure flow meter having a temperature sensor with a safe structure and a pressure-integrated sensor capable of simultaneously measuring pressure and differential pressure and measuring flow.
According to claim 1,
The high-pressure sensor unit 210 is configured to include a pressure measuring sensor 211 and a filter converter 212,
The low pressure sensor unit 220 is a temperature sensor of a safe structure, characterized in that it includes a low pressure pressure measuring sensor 221 and a low pressure filter converter 222, and simultaneously measures pressure and differential pressure and measures the flow rate. Differential pressure flow meter with integrated pressure sensor.
According to claim 1,
A communication unit 250 is added to the pressure integrated sensor 200 and connected to a wired/wireless communication device to transmit pressure information, flow rate information, water level information, etc., and to receive information so that the calculation program mounted on the calculation unit can be updated. A temperature sensor with a safe structure capable of simultaneously measuring pressure and differential pressure and measuring flow or water level, characterized in that it can perform the function, and a pressure integrated sensor capable of simultaneously measuring pressure and differential pressure and measuring flow. Differential pressure flow meter.

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