KR20050010449A - Low Power-Consuming Flow Sensing System - Google Patents

Abstract

PURPOSE: A flow sensing system consuming low power is provided to measure the amount of the flow by using one pole. CONSTITUTION: A flow sensing system consuming low power includes an impeller, a pole detecting sensor, and a magnetic part. The impeller rotates according to the flow of the fluid. The pole detecting sensor detects the change of poles so as to deliver the change information to a central processing unit. The magnetic part allows the pole detecting sensor to detect the change of the poles by rotating with a pole. The flow sensing system has a first pole detecting sensor(112) and a second pole detecting sensor(114) and measures the direction of the flow according to which pole detecting sensor first recognizes the change of poles of the magnetic part.

Description

Low Power-Consuming Flow Sensing System

The present invention relates to a system that reduces power consumption when detecting a flow rate by modifying a magnetic part in a flow sensing device, and more specifically, uses only one polarity when operating a flow sensing device by magnetizing or modifying a shape of a magnetic part in a flow sensing device. The present invention relates to a flow sensing system that reduces power consumption.

Flow sensing devices are used in water piping in home and industrial boilers, water meters, water purifiers, automobiles, and air conditioners. In addition to the industrial calorimeter, the amount of fluid flow inside the household calorimeter installed in each household in a group residence, such as an apartment or apartment house with central and district heating, is used to display the calories used by each household. A flow sensing device is used to calculate.

1 is a schematic block diagram of a conventional flow sensing system.

The flow rate sensing system includes a flow rate sensing unit 110, a display unit 120, a central processing unit 130, a memory 140, a battery 150, a battery monitoring unit 160, and a communication unit 170.

Here, the flow rate sensing device 110 is composed of a first sensor 112, a second sensor 114, a magnetic portion 116 and an impeller 118. When the fluid starts to flow through the supply pipe, the impeller 118 rotates. When the impeller 118 starts to rotate, the magnetic part 116 connected to the same rotating shaft as the impeller 118 also rotates. As the magnetic unit 116 rotates, the first sensor 112 and the second sensor 114 detect a change in the polarity of the magnetic unit 116, and transmit the detected result to the central processing unit 130. The second sensor 114 works with the first sensor 112 and is used to determine the flow direction and the flow rate of the fluid.

When the fluid flows from left to right as in the example of FIG. 1, the second sensor 114 first detects the change in the magnetism, and then the first sensor 112 detects the change in the magnetism. In the case where the fluid flows in the opposite direction, the first sensor 112 first detects the change in the magnetic property, and then the second sensor 114 detects the change. As such, the direction in which the fluid flows may be determined according to which part of the first sensor 112 and the second sensor 114 detects a change in magnetic property.

When the number of changes in the direction and the direction of the fluid is measured by the first sensor 112 and the second sensor 114 and transmitted to the central processing unit 130, the central processing unit 130 is These signals are calculated and converted into values of the flow rate and then displayed through the display unit 120. The display unit 120 displays not only the flow rate but also information of the flow rate sensing system such as the flow rate and the device state so that the operator can view the flow rate.

The first and second sensors 112 and 114 mainly use a magnetoresistive (MR) sensor or a hall (Hall) sensor. The MR sensor is a sensor using a magnetoresistive effect. It is a sensor that can be detected by the change of, and the Hall sensor is a sensor used to detect the speed or position by using the Hall electromotive force generated by the magnetic field according to the Hall Effect.

The memory 140 stores information required by the flow rate sensing system having the same flow rate value, flow rate, direction, and the like.

The battery 150 has a life span of at least 5 years when the battery 150 supplies the power required for the flow sensing system but is installed once due to the characteristics of the flow sensing system that is difficult for the operator to maintain frequently. The battery monitoring unit 160 monitors the state of the battery 150, for example, whether there is an abnormality, a residual voltage, and notifies the central processing unit 130.

The communication unit 170 is connected to a wired / wireless network or a telephone network (PSTN), and performs a function of transmitting a weighing value and various flow rate information to a meter reading center (not shown).

2 is a view showing the magnetic portion 116 of the conventional flow sensor.

The magnetic part 116 is a part which rotates together with the impeller 118 to measure the flow rate and the direction of the fluid, and the N pole 210 and the S pole 220 which rotate about the rotation axis 230 and the rotation axis 230. It is made of a magnet with. When the impeller 118 rotates as the fluid flows, the magnet also rotates due to the rotation of the rotating shaft 230. Due to the rotation of the magnet, the first sensor 112 and the second sensor 114 alternately detect the N pole 210 and the S pole 220, so that the polarity is N pole-> pole-> S pole-> pole-free- > N pole-> no pole-> ... is repeated repeatedly.

When the impeller 118 rotates once, the pole change of the magnet occurs at least four times: N pole-> pole-> S pole-> pole. Thus, the first sensor 112, the second sensor 114, and the central processing unit 130 operate more than four times when the impeller 118 rotates one time, and the central processing unit 130 also operates in other parts of the system. The battery 150 is consumed in the process of processing four or more results. Therefore, the conventional flow detection system uses a large capacity battery, the short life of the battery is a disadvantage.

In order to solve the above problems, the present invention provides a system capable of measuring the flow rate while using a small amount of power consumption using only one polarity when the flow sensing device operates by magnetizing or deforming the magnetic part in the flow sensing device. Its purpose is to provide.

1 is a schematic block diagram of a conventional flow sensing system;

2 is a view showing a magnetic part of a conventional flow sensing device;

3 is a view showing a magnetic part of the flow rate sensing apparatus according to the present invention.

<Description of Symbols for Main Parts of Drawings>

110: flow rate detection device 112: first sensor

114: second sensor 116: magnetic part

118 impeller 120 display unit

130: central processing unit 140: memory

150: battery 160: battery monitor

170: communication unit 210: N pole

220: S pole 230: rotation axis

310: magnetic material 320: non-magnetic material

In order to achieve the above object, the present invention, by measuring the parameters such as the flow rate, the flow rate according to the flow of the flow using only a magnetized part, in the flow rate sensing system to reduce power consumption, using a magnetized part only Flow rate detection unit for measuring the flow rate and the flow of the fluid; A central processing unit for calculating a parameter by calculating a detection signal transmitted from the flow rate detection unit; A display unit which receives information including a flow rate, a flow rate, and a device state from a central processing unit and displays the information for viewing by a user; A memory for storing information including flow rate, flow rate, and instrument status; A battery for supplying power required for the flow sensing system; A battery monitoring unit for monitoring a capacity or state of a battery and transmitting the battery to a central processing unit; And a communication unit connected to the communication line to transmit the parameter.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

3 is a view showing the magnetic portion 116 of the flow rate sensing apparatus according to the present invention.

According to the present invention, instead of the conventional magnet divided into the N pole 210 and the S pole 220 in the magnetic part 116, the magnets 112 and 114 may use the magnet to detect only one pole of the N pole or the S pole. To transform. This is possible by modifying the shape of the magnet or magnetizing it. Here, magnetization refers to placing a magnetic field in a permanent magnet that makes it difficult to recover its original state by putting a strong magnetic field on a solid and aligning its direction in one direction. In this way, the material is changed to the magnetic material 310 having one polarity. In the present invention, it is not important whether the magnetic body 310 is made of the north pole or the south pole.

When the magnet is deformed, as shown in FIG. 3, the first and second sensors 112 and 114 are connected to the N pole, the first and second electrodes so that the first and second sensors 112 and 114 recognize only the N pole. The lower opposite side of the sensors 112 and 114 is transformed into the S pole. Alternatively, the first and second sensors 112 and 114 may be S poles, and the lower opposite side may be deformed to N poles so that the first and second sensors 112 and 114 recognize only the S poles. .

In the case of the magnetization method, magnets are applied to the magnetic body 310 of FIG. 3 to form an N pole or an S pole.

In this way, half of the magnet is made of magnetic material 310 having polarity, and the other half is made of non-magnetic material 320 having no polarity.

The magnet made in this way has two polarity changes while rotating together when the impeller 118 is rotated once by the fluid. In the case where the magnetic body 310 is the N pole, the first and second sensors 112 and 114 repeat the second change of the N pole-> non-polarity, whereas when the magnetic body 310 is the S pole, the S pole-> non-pole Repeat the change.

As the number of polarity changes recognized by the first and second sensors 112 and 114 is reduced from 1/2 to 4 times in two, the operation frequency of the first and second sensors 112 and 114 is also 1/2. And the number of operations of the central processing unit 130 is also reduced to 1/2. For example, if the impeller 118 rotates 100 times per second, when the number of changes in polarity is four times by the existing magnetic part 116 configuration, the number of operations of the sensors 112 and 114 is measured for flow rate measurement. It should be 400 with 100 × 4. However, when the number of changes in polarity is two, according to the embodiment of the present invention, the sensors 112 and 114 can measure the flow rate, the flow rate, and the like if the sensor 112 and 114 operate only 200 times.

In addition, as the number of operations of the sensors 112 and 114 is reduced to 1/2, the number of calculations in the central processing unit 130 is also reduced to 1/2. In addition, the number of operations of the display unit 120, the memory 140, the communication unit 170, and the like is also reduced to 1/2, and thus, the overall power consumption of the flow sensing system is reduced to 1/2. To be more precise, a significant amount of power consumption is reduced, although not exactly reduced to half, which is a great advantage for flow meters where battery life is a very important factor.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

As described above, according to the present invention, it is possible to configure a flow rate sensing system in which power consumption is reduced by almost half by simply changing the shape or magnetization configuration of the magnet of the magnetic part without greatly modifying the existing system. Therefore, even if the same battery is used, it is possible to extend the use time by approximately two times, thereby extending the replacement time of the battery.

Conversely, it is also possible to reduce the size of the battery by about 1/2, it is possible to reduce the size of the equipment of the flow sensing system, and the cost of the equipment is advantageous.

Claims (8)

In the flow rate sensing system that reduces power consumption by measuring parameters such as flow rate, flow rate, etc. according to the flow rate of the flow using only a partially magnetized magnet, A flow rate sensing unit measuring the flow rate and the flow of a fluid by using the magnetized part only; A central processing unit for calculating the parameter by calculating a detection signal transmitted from the flow rate detecting unit; A display unit which receives the information including the flow rate, the flow rate, and the device state from the central processing unit and displays the user information for viewing; A memory for storing information including the flow rate, the flow rate, and the device state; A battery for supplying power required for the flow sensing system; A battery monitoring unit which monitors the capacity or state of the battery and transmits the battery to the central processing unit; And Communication unit connected to the communication line for transmitting the parameter Flow detection system comprising a. The method of claim 1, wherein the flow rate detection unit, An impeller rotating according to the flow of the fluid; A polarity sensing sensor that senses a change in polarity and transmits it to the central processing unit; and Magnetic part having a polarity and rotating to allow the polarity sensing sensor to sense a change in polarity Flow detection system comprising a. The method of claim 2, wherein the polarity detection sensor, And a first polarity sensing sensor and a second polarity sensing sensor, which measures the direction of the fluid according to which sensor first recognizes the magnetic change of the magnetic part. The method of claim 2, wherein the polarity detection sensor, Flow sensing system using MR sensor which detects the change of magnetic field and the presence or absence of magnetic body by the change of voltage by using magnetoresistive effect or Hall sensor which is used to detect speed or position The method of claim 2, wherein the magnetic portion, And a magnet made to allow the polarity sensing sensor to recognize only one polarity during rotation, and a rotating shaft connected to the impeller to rotate the magnet according to the impeller rotation. The method of claim 5, wherein the magnet, It is a magnetization method that puts a magnetic field on a permanent magnet that makes it hard to recover its original state by applying a strong magnetic field to one direction, or by changing the shape of the magnet so that only the polarity of either N pole or S pole is used. And a sensor for recognizing the sensor. The method of claim 5, wherein the magnet, A flow sensing system, characterized in that the half is made of a magnetic material having a polarity, the other half is made of a non-magnetic material having no polarity. The method of claim 1, wherein the communication unit, And a parameter measured by the flow sensing system to a meter reading center using a public switched telephone network (PSTN) or wired or wireless communication.