KR101963049B1 - An absolute liquid level measuring equipment for preventing freeze having timing pulley - Google Patents

Abstract

The present invention relates to a water level measuring apparatus, which can prevent freezing in winter by incorporating a heater in a float in direct contact with water and allows precise water level measurement by transmitting vertical movements of the float to a timing pulley through a timing belt. The water level measuring apparatus according to the present invention, which performs water level measurement by using a float (20), includes the float (20) floated on a water surface by buoyancy and moving up and down with water level fluctuations; a timing pulley (40) receiving and converting into a rotation amount the vertical movement amount of the float (20) moving up and down with the water level fluctuations; and a water level gauge (10) calculating an absolute position value of the float (20) by receiving the rotation amount of the timing pulley (40) and calculating a water level value in accordance with the calculated absolute position of the float (20). The vertical movement amount of the float (20) is transmitted to the timing pulley (40) through a timing belt (30) and is converted into the rotation amount.

Description

TECHNICAL FIELD [0001] The present invention relates to a water level measuring apparatus for preventing ice from freezing in a winter season,

The present invention relates to a water level measuring apparatus, and more particularly, to a water level measuring apparatus capable of preventing a freezing in winter by incorporating a heater in a float directly contacting water, and transmitting the up and down movement of the float to a timing pulley through a timing belt, The present invention relates to a water level measuring apparatus.

Level meters for measuring the level of dams, rivers or harbors, liquid levels in reservoir tanks in oil refineries, crude oil levels in crude oil storage facilities stored in rock walls, and water level in water supply facilities are very important roles Is one of the facilities in charge of.

Generally, a float is installed on the water level so that it can move up and down according to the water level by the water level measurement method, the wire rope is connected to the float, the water is wound on the pulley of the water level measuring device, A method of measuring the water level by sensing the movement of the wire rope through the amount of rotation of the pulley is mainly used.

On the other hand, there is a case where the water surface is frozen at a low temperature in the winter season. When the water surface is frozen, the float is isolated from the water surface, and it is difficult to measure the accurate water level.

Various methods have been proposed to solve the problem of water level measurement due to the water surface freezing. FIG. 1 shows an example of a device for preventing freezing by using a conventional steel pipe heater. As shown in Fig. 1, in order to prevent freezing, a steel pipe heater 5 is installed over a wide range of steel pipe walls to prevent freezing of the water surface where the float 1 is located. The process of installing the heater 5 is difficult and the heater 5 exposed to the air may overheat and a short circuit may occur at the heater 5 in the water, There are disadvantages.

Fig. 2 shows an example of a method of preventing ice formation by providing a heater inside a float by another method. 2, a heater is provided inside the float 1 to prevent freezing. The heater is supplied with power from the heater power line 6 connected to the float 1 through a lower portion thereof . In this method, the portion of the heater power line 6 that is immersed in the water and connected to the float 1 is very difficult to be waterproofed, and there is a fear that a short circuit may occur, and the heater power line 6 may interfere with the up / down movement of the float 1 In addition, when the float 1 is pulled down by the weight of the heater power line 6 immersed in the water, the water level measurement error is caused. Also, when the water depth is set at a low water depth, So that the float 1 can not move even if the water level becomes high.

In this conventional level gauge, a wire rope made of stainless steel is used to transmit the vertical movement amount of the float to the pulley. FIG. 3 is a conceptual diagram showing a method of transferring the amount of movement of the float to the pulley by using the conventional wire rope And Fig. 4 shows a coupling structure of the wire rope and the pulley.

As shown in Figs. 3 and 4, a stainless wire rope 2 is used to transmit the up and down movement amount of the float 1 located at the water level to the pulley 3. A lead ball 2a is fixedly attached to the stainless wire rope 2 at regular intervals and a lead ball 2a fixed to the stainless wire rope 2 is inserted into a lead ball groove 3a And the vertical movement amount of the float 1 is transmitted to the pulley 3.

In the combined structure of the wire rope 2 and the pulley 3 having the above structure, when the rapid water level fluctuation occurs, the stainless wire rope 2 may be separated from the pulley 3, If the lead balls (stainless balls) 2a fixed to the wire rope 2 are not provided at regular intervals, the accuracy of the water level measurement may be problematic.

For example, the pulley V groove 3b formed in the pulley 3 is generally machined to have a circumferential length of 1 m (1000 mm) and a diameter of 318.3099 mm. When an error occurs, the length of the wire rope 2 The circumferential length of the circumferential length measuring the circumferential length of the circumferential groove is fundamentally an error. For example, when machining the pulley V groove 3b coupled with the stainless steel wire rope 2, the diameter of the stainless wire rope 2 is only about 1.5 mm, and when the pulley V groove 3b is machined, 318.3099mm, the machining is very difficult, which leads to a machining error in diameter. If an error occurs in the diameter, an error occurs in the circumference length of 3.14 times. Further, since the pulley V groove (3b) is narrow, it is difficult to accurately control the thickness of the coating, do. At this time, when the water level fluctuation is large like the dam, the number of revolutions of the pulley 3 increases, so that the position of the lead ball groove 3a in the lead ball (2a) and the pulley (3) , The water level measurement error is generated, and the wire rope 2 is released from the pulley 3, making measurement impossible.

If a circumferential length of the pulley V groove 3b is 1 m (1000 mm) and a diameter is 318.3099 mm, assuming that an error of 0.3 mm in diameter is generated in machining and an error of 0.2 mm in thickness of the coating occurs, The sum of the errors is 0.5 mm, resulting in 318.3099 mm + 0.5 mm = 318.8099 mm, and the circumferential length (L) is 318.8099 * 3.1415926535 = 1,001.571 mm, resulting in an error of 1.571 mm.

If the water level fluctuation of 3 m is measured by an apparatus generating such an error, an error of 4.713 mm is generated. Also, the position of the lead ball groove 3a in the lead ball 2a and the pulley 3 is shifted So that the wire rope 2 slips on the pulley 3, causing a large error in the measured value. This phenomenon is a fundamental problem of all water level measuring devices currently installed, and a solution thereof is required.

Korean Registered Patent No. 10-0656072 (Registered on December 4, 2006)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the conventional art, and it is an object of the present invention to provide a timing pulley which can precisely measure the level by transmitting a vertical movement amount of a float to a timing pulley through a timing belt, The present invention also provides a water level measuring apparatus provided with a water level measuring device.

Another object of the present invention is to provide a water level measuring apparatus for preventing freezing of ice during winter, which is capable of safely preventing freezing in winter by driving a heater built in a float through a heater power line not contacting water.

According to another aspect of the present invention, there is provided a water level measuring apparatus comprising: a float which floats on a water surface and moves up and down according to a variation of a water level; and a float that receives up- And a water level gauge for calculating an absolute position value of the float by receiving the rotation amount of the timing pulley and calculating a water level value according to the calculated absolute position of the float, Is transmitted to the timing pulley through a timing belt having a plurality of steel wire cores and is converted into a rotation amount, one end of the timing belt is movably engaged with a link device formed on the float through a belt fixing plate , A slip prevention groove is formed in the belt fixing plate, and the timing belt is fixed to the belt fixing plate The float is provided with a heater, and is supplied with power from a power supply unit installed on the ground, and is driven by being coupled with an upper portion of the float, And the other end of the timing belt passing through the timing pulley is fixed to a power supply unit provided on the ground via a roller and is further coupled to the lower end of the roller so as to provide tension to the timing belt passing through the roller, A heater power line is connected to the heater, and the heater power line is connected to a heater incorporated in a float via a heater power source pulley formed on a side surface of the roller and the timing pulley, And the rotation of the heater power pulley is influenced by the rotation of the timing pulley It is desirable to avoid beating.

delete

delete

delete

The gauge includes a precision encoder, which is an absolute encoder for precise measurement, which is coupled to a rotating rotary shaft through rotation of a timing pulley via a coupling, measures and outputs a value corresponding to the rotation angle of the rotary shaft, A reduction gear provided on the shaft of the gear provided at the last end of the reduction gear and measuring and outputting a value according to the rotation angle of the reduction gear; An absolute displacement meter having a wide-angle encoder; And a liquid level measurement controller for calculating an absolute position value of the float by analyzing output values of the precision encoder and the wide-angle encoder of the absolute displacement meter and calculating a water level value according to the calculated absolute position of the float, And a log data memory for sequentially writing a time stamp indicating a time at each time and a water level data at that moment, a voltage of a charging device, and a door open state in a memory. When a data transfer command is received from a remote main terminal, It is preferable that the data is extracted from the data stored in the memory and transmitted to the main terminal device through the CDMA modem or the LET modem or the radio signal transmitting and receiving section.

The level measuring apparatus according to the present invention has an effect of enabling precise level measurement by transmitting the amount of up and down movement of the float to the timing pulley through a timing belt capable of precise power transmission.

Further, the water level measuring apparatus according to the present invention stably supplies power to the heater provided inside the float through the heater power supply line which does not restrict the float up and down movement and does not contact the water, It is possible to prevent freezing in the winter season.

1 is an example of a device for preventing freezing by using a conventional steel pipe heater,
Fig. 2 shows an example of a method of preventing icing by providing a heater in a conventional float,
3 is a conceptual diagram showing a method of transferring a movement amount of a float to a pulley using a conventional wire rope,
Fig. 4 is a schematic view of a conventional wire rope and a pulley,
FIG. 5 is an overall configuration diagram of a water level measuring apparatus provided with a heater built-in float according to the present invention;
6 is a structural view of a timing pulley according to the present invention;
Fig. 7 is a view showing a coupling structure of a timing belt and a float according to the present invention,
8 is a structural view of a timing belt applied to the present invention,
FIG. 9 is an example of a system for supplying power to a heater of a float according to another embodiment of the present invention,
10 is a plan sectional view of a float according to the present invention,
11 is a conceptual diagram illustrating a system for supplying power to a heater according to another embodiment of the present invention;
12 is a plan view of the water level meter of the water level measuring apparatus according to the present invention,
FIG. 13 is a plan view and partial sectional view of an absolute displacement meter according to the present invention,
14 is a diagram showing the output value relationship between the precision encoder and the wide-angle encoder according to the present invention,
15 is an example of a method of detecting the number of revolutions of a wide-area encoder according to the present invention,
16 is a diagram showing a change in value of a precision encoder with respect to a change in value of a wide-angle encoder due to a backlash existing between gears,
17 is a conceptual diagram for measuring the number of revolutions of a precision encoder using a wide-range encoder value according to the present invention,
FIG. 18 is a block diagram showing the precision encoder rotation speed determination table,
19 shows an example of a simulation result of continuous movement of the precision encoder and the wide-angle encoder according to the present invention in an Excel program,
20 is a block diagram of a level meter according to the present invention;
21 is an example of a system diagram of a terminal device for measuring and collecting a dam level or a river water level,
22 to 24 show an example of characteristics of a windowed-sinc filter according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

5 is a view showing the entire construction of a water level measuring apparatus provided with a heater built-in float according to an embodiment of the present invention.

5, the water level measuring apparatus according to the present invention includes a heater built-in float 20 floating on a water surface to be measured and moving up and down according to a change in water level, A timing belt 30 for transferring the up and down movement amount of the float 20 to the timing pulley 40 and a timing belt 30 for converting the weight of the float 20 to a timing belt A power supply unit 60 for supplying power to the heater built-in float 20 and a float 20 for detecting the amount of rotation of the timing pulley 40, And a water level meter (10) for measuring the water level.

In the present invention, in order to solve the problems occurring in the process of transferring the up and down movement of the float to the pulley through the conventional stainless wire rope, an industrial timing belt 30 and a timing pulley 40 are applied. The timing belt 30 and the timing pulley 40 applied to the present invention are standardized and manufactured precisely globally and in particular the timing pulley 40 and the timing belt 30 are formed with many teeth to be coupled to each other The power is transmitted firmly, so that the slipping phenomenon does not occur. On both sides of the timing pulley 40 on both sides of the timing pulley 40 are provided belts 30 for bringing the timing belt 30 into close contact with the timing pulley 40 in order to prevent the timing belt 30 from being peeled off from the timing pulley 40, A pushing bearing 45 and a freeze prevention heater 46 for preventing the timing belt 30 from freezing on the timing pulley 40 during the winter season are provided.

In the embodiment of the present invention, the timing belt 30 uses a timing belt having a pitch of 3 mm and the number of teeth of the timing pulley 40 is 330. Accordingly, the entire circumferential length L is 990 mm (L = pitch The number of teeth = 3 * 330). At this time, the circumferential length value is stored in the memory of the water gauge 10, and the travel distance of the float 20 built in the heater per revolution of the timing pulley 40 is calculated through the controller.

6 is a structural view of a timing pulley according to an embodiment of the present invention.

As shown in FIG. 6, the body 41 of the timing pulley 40 is machined to have a tooth shape so as not to slip when it contacts the timing belt 30, and is formed to have a number of teeth of 330 to form a pulley. The guide plates 42 are formed on both sides of the pulleys 40 so as not to be separated from the pulleys 40. In the embodiment of the present invention, the guide plate 42 is fixed to the body 41 through a guide plate fixing screw 43.

Fig. 7 shows a coupling structure of a timing belt and a float according to an embodiment of the present invention.

7, a link device 37 to which the timing belt 30 is fastened is coupled to an upper portion of the float 20 in which the heater is built. The link device 37 has two Axis is formed. The link device 37 is hinged to the upper portion of the float 20 so that the float 20 is free from movement along the water surface and the timing belt 30 is wrapped and joined to the upper shaft. At this time, the timing belt 30, which overlaps in two layers through the upper shaft of the link device 37, is screwed and fixed through the belt fixing plate 35 from the front and rear sides.

On the other hand, in order to prevent the belt fixing plate 35 from slipping off the slippery timing belt 30, the belt fixing plate 35 is provided with a slip prevention groove (not shown) in which the surface of the timing belt 30 can protrude 36 are formed. That is, when the screw of the belt fixing plate 35 is screwed on the front and rear surfaces of the timing belt 30 against the surface of the timing belt 30, the surface of the timing belt 30 protrudes into the slip prevention grooves 36, It is possible to prevent the belt fixing plate 35 and the timing belt 30 from being separated from each other even if vibration occurs due to the surface of the timing belt 30.

5, the float 20 is provided with a heater for preventing the water surface of the winter season from freezing. The heater built in the float 20 is powered by a power supply unit 60 installed on the ground Is supplied and driven. In order to balance the weight of the float 20, the counterweight 50 applies a constant tension to the timing belt 30 while moving up and down according to the water level fluctuation. At this time, the counterweight 50 moves the timing belt 30 To ensure smooth movement of the timing belt 30. The timing belt 30 can be moved in the direction of the arrow A in FIG. The other end of the timing belt 30 which is coupled with the float 20 and passes through the timing pulley 40 and the roller 55 is fixed on the ground. In the embodiment of the present invention, Is fixed to a power supply unit (60) which is installed on the ground and supplies power to the heater of the float (20).

In the present invention, in order to prevent the expansion and contraction of the timing belt 30 due to the weight of the float 20 and the counter weight 50 with a heater at a relatively long distance and to prevent the shape change due to long- A timing belt 30 having a structure including an iron core 31 (shown in Fig. 8) is used. The positive power supply line 32 of the power supply unit 60 is connected to a part of the steel wire core 31 provided inside the timing belt 30 and the negative power supply line 33 is connected to the other part. And power is supplied to the heater of the float 20. FIG. 8 shows the structure of the timing belt applied to the present invention.

In the embodiment of the present invention, the counterweight 50 is heavily weighted twice as much as the weight connected to the conventional wire rope shown in FIG. 1, which is applied to the rollers 55 around the counterweight 50, The weight of the counterweight 50 must be doubled in order to provide the tension to each timing belt 30 as shown in Fig.

The power supply may be provided to the heater provided in the float 20 by using a separate heater power line without using the timing belt 30 provided with the steel wire core 31. FIG. And an example of a system for supplying power to a heater of a float according to another embodiment is shown.

9, the up / down movement amount of the float 20 which floats on the water surface to be measured and moves up and down in accordance with the change of the water level is transmitted to the timing pulley 40 through the timing belt 30, A heater power line 75 is connected to an upper portion of the float 20 and the heater power line 75 is connected to a heater power pulley 70 So that the heater of the float 20 is supplied with electric power. At this time, in order to prevent the vertical movement of the heater power supply line 75 due to the up-and-down movement of the float 20 from affecting the rotation of the timing pulley 40, 71). The heater power supply line 75 passing through the heater power pulley 70 is connected to the power supply unit 60 through another roller formed on the side surface of the roller 55, To the heater of the float (20).

The heater power supply line 75 wound around the heater power pulley 70 can supply power to the heater provided inside the float 20 at the upper portion of the float 20 without restricting the up and down movement of the timing belt 30. [ Can be supplied stably.

10 is a plan sectional view of a float according to an embodiment of the present invention.

10, a heater 21, a temperature regulator 22 for regulating the temperature of the heater 21 at a predetermined temperature, and a heater power line are connected to the inside of the float 20 and connected to the heater 21 A terminal block 25 for supplying power is provided. An upper portion of the float 20 is covered with a lid 23. An edge of the float where the lid 23 and the float meet is provided with an oil ring 24 which is a urethane packing for preventing water from permeating.

Meanwhile, a method of supplying power to the heater 21 of the float 20 can be variously modified. FIG. 11 is a conceptual diagram showing a system for supplying power to the heater according to another embodiment of the present invention. 11, the heater 21 built in the float 20 receives power from the timing belt 30 through which the power is supplied through the steel wire core 31. The timing belt 30 A power supply roller 80 may be provided on one side of the timing belt 30 to supply power to the steel wire core 31 so as to contact the steel wire core 31. [

Hereinafter, a method of measuring the water level through the water level measuring apparatus having the above configuration will be described in detail.

12 is a plan view of the water level meter of the water level measuring apparatus according to the embodiment of the present invention.

12, the water level gauge 10 of the level gauge is provided for supporting a timing pulley 40 that receives the vertical movement amount of the heater built-in float 20 through the timing belt 30 and converts it into a rotation amount A coupling 162 for transmitting the amount of rotation of the timing belt pulley 40 to the absolute displacement gauge 100 and a control unit 160 for measuring and outputting the amount of rotation transmitted through the coupling 162, A water level measuring controller 200 for analyzing an output value of the absolute displacement meter 100 and calculating an absolute position value of the heater built float 20 to measure a water level value, A LCD & KEY board 161 for displaying status values of the level meter 200 and inputting parameters related to the water level measurement, a CDMA modem or an LTE modem for transmitting the status values of the water level measuring controller 200 to the outside in a wireless manner The wireless communication unit 165 .

The absolute displacement meter 100 installed in the water level meter 10 measures the amount of rotation transmitted through the coupling 162 and transmits the measured amount of rotation to the water level measuring controller 200. The water level measuring controller 200 detects the absolute displacement meter 100 The absolute position of the heater built-in float 20 according to the up-and-down movement is calculated, and the absolute water level value is calculated through the calculation.

In the embodiment of the present invention, the absolute displacement gauge 100 measures the amount of rotation of the timing pulley 40 in accordance with the vertical movement of the heater built-in float 20 through the absolute encoder, It is possible to measure the amount of movement even after the power is cut off, so that the amount of rotation of the timing pulley 40 is measured and supplied to the water level measuring controller 200 as soon as power is supplied. On the other hand, since the absolute type encoder can measure only the movement amount with respect to the distance within one revolution, in the present invention, by using two absolute type encoders connected with the reduction gear, the measurement limit within one rotation can be overcome, So as to precisely measure the amount of movement with respect to the moving object.

An absolute displacement meter 100 that receives the amount of rotation of the timing belt pulley 40 through the coupling 162 and measures the amount of rotation of the timing belt pulley 40 will be described below.

13 is a plan view and partial sectional view of an absolute displacement meter according to an embodiment of the present invention.

13, the absolute displacement meter 100 according to the present invention includes a rotation shaft 104 that receives a rotation amount of the timing belt pulley 40 via a coupling 162 and rotates, A precision encoder 112 which is an absolute encoder for precision measurement which is coupled to the rotary shaft 104 and outputs a unique value according to the rotation angle of the rotary shaft 104; And a wide-angle encoder 113, which is an absolute encoder for wide-area measurement, which outputs a unique code value according to the rotation angle reduced by the reduction gear 106 .

The rotation shaft 104 is rotated by receiving the amount of rotation of the timing belt pulley 40 through a coupling 162. The bearing 103 is inserted into the rotation shaft 104 so that the rotation can be smoothly performed .

The precision encoder 112 coupled to the rotation shaft 104 is an absolute type encoder that outputs a unique code value for an arbitrary rotation angle within one rotation of the rotation shaft 104. The precision encoder 112, And outputs an eigenvalue corresponding to the rotation of the rotary shaft 104 according to the resolution, thereby accurately measuring the amount of movement of the rotary shaft 104 within one rotation.

A gear 105 is formed on the rotary shaft 104 and a reduction gear 106 for reducing the rotation speed of the rotary shaft 104 is coupled to the gear 105. In the embodiment of the present invention, And a plurality of gears that are sequentially coupled to the rotary shaft 104 and sequentially decelerate the rotary speed of the rotary shaft 104. That is, in the embodiment of the present invention, the reduction gear 106 includes a first gear 107a, a second gear 107b, and a third gear 107c having appropriate deceleration ratios, The number of reduction gears 106 and the gear ratio can be appropriately changed according to the movement range of the detection subject and a speed reducer or a harmonic driver or the like constituted by a single component can be used by another deceleration method It is possible.

A wide-angle encoder 113 is coupled to the shaft of the third gear 107c located at the last end of the reduction gear 106 that decelerates the rotation speed of the rotary shaft 104. The wide- Is an absolute type encoder that outputs a unique code value for an arbitrary rotation angle within one revolution of the third gear 170c whose rotation speed of the rotation shaft 104 is reduced by the reduction gear 106. [ That is, the third gear 107c makes one rotation when the rotation shaft 104 rotates several times according to the deceleration ratio with respect to the rotation shaft 104. The wide-angle encoder 113 rotates the third gear 107c , The eccentricity can be measured over a wide range corresponding to the number of rotations of the rotary shaft 104.

The values output through the precision encoder 112 and the wide-angle encoder 113 are transmitted to the water level measuring controller 200. The water level measuring controller 200 is connected to the rotation axis 104 in which the precision encoder 112 is installed and the wide- The output value of the precision encoder 112 and the wide-angle encoder 113 is analyzed in consideration of the deceleration rate and the backlash error of the third gear 107c provided with the water level sensor 113, Value.

Hereinafter, the process of calculating the water level value by analyzing the measured values of the precision encoder 112 and the wide-angle encoder 113 by the water level measuring controller 200 will be described.

Since the absolute water level indicating the water level is determined according to the change in the position of the float 20, it can be obtained by calculating the change in the position of the float 20 moving in accordance with the water level change at the reference position. That is, the absolute position is calculated by calculating the distance traveled by the float 20 with reference to the reference floor, and the absolute position of the float 20 is calculated using the wide encoder 113, 112 and multiplying the calculated number of rotations of the precise encoder 112 by the resolution of the precise encoder 112 and adding the value of the precise encoder 112 thereto.

The easiest way to calculate the number of revolutions of the precision encoder 112 is to calculate the number of revolutions of the precision encoder 112 at a moment when the value of the precision encoder 112 is changed from 1023 to 0 The number of revolutions of the precision encoder 112 may be reduced by one at the instant when the number of revolutions of the precision encoder 112 is increased by 1 and the number of revolutions of the precision encoder 112 is changed from 0 to 1023. However, this method can not be applied because the number of rotations of the precision encoder 112 can not be calculated by reading the value of the wide-angle encoder 113 at the moment when the power is turned on. In this method, the number of revolutions before the power is turned off is stored in the backup memory. When the power is supplied, the value is read to know the number of revolutions until the power is supplied. However, if the float 20 moves The moving amount at this time can not be calculated, and as a result, it can not be applied to the absolute position measurement of the float 20.

FIG. 14 is a graph showing an output value relationship between a precision encoder and a wide-angle encoder according to an embodiment of the present invention, and FIG. 15 shows an example of a method of detecting the number of rotations of a wide-angle encoder.

15, assuming that a wide-area encoder value is 1021 at time t, 1022 at time t + 1, P1 at time t + 2, and 3 at time t + 3, If the difference between the measurement value and the previous measurement value exceeds the set value range (for example, 950) and the difference value is negative, the value of the wide-angle encoder is incremented by 1, and if the difference value is positive, This value is periodically stored in three consecutive memories (Mn, Mn + 1, Mn + 2) for storing the position of the wide-angle encoder 113 in order to compensate for errors that may occur when writing to or reading from memory . When the power is turned on, the controller reads the values stored in the three memories (Mn, Mn + 1, Mn + 2) for storing the position of the wide-angle encoder 113 and selects two identical values, And if the values of the three memories (Mn, Mn + 1, Mn + 2) are all different, a function of generating a position detection error is performed.

The values of the precision encoder 112 and the wide encoder 113 are referred to as ENC1_OUT, ENC2_OUT and ENC2_MEM, respectively, When the resolution is defined as 1024, the absolute position value ENC_POS due to the movement of the float 20 can be expressed by the following equation (1).

Here, f {} indicates a method of calculating the number of revolutions of the precision encoder 112 using the position storage memory value ENC2_MEM and the value ENC2_OUT of the wide-angle encoder 113. [

In the process of calculating the number of revolutions of the precise encoder 112 using the value of the wide-angle encoder 113, it is assumed that the number of revolutions of the precise encoder 112 at this time is 90 revolutions with respect to the total stroke length of the moving block And the resolution of the wide-angle encoder 113 is 1024, the value A1 of the wide-angle encoder 113 for one rotation of the precision encoder 112 is calculated by the following equation (2).

The value of the wide-angle encoder 113 for one rotation of the precision encoder 112 is not an integer and as a result of the backlash existing between the screw and the nut, the value of the wide- The calculation of the number of rotations of the encoder 112 is complicated.

16 is a graphical representation of a change in the value of the precision encoder 112 with respect to a value change of the wide-angle encoder 113 due to backlash existing between the gears. As shown in Table 1, when the value of the wide- The value obtained by dividing the value of the wide-angle encoder 113 by the value A1 of the wide-angle encoder 113 for one revolution of the precision encoder 112 as shown in Equation 2 is used as the number of revolutions of the precision encoder 112 And a process of causing a large error in calculation.

If the position value [A] of the precise encoder 112 is 987, the theoretical position [B] of the wide-angle encoder 113 is 10.9667, and the output of the actual wide- ], So 10 is output. Therefore, the precision encoder rotation speed determination value [D] is a value obtained by dividing the wide encoder value [C] by 11 based on the equation (2), and the absolute position calculation value [E] D] is multiplied by 1024, which is the resolution of the wide-angle encoder, and the value obtained by adding the precision encoder position value [A] to this value (absolute position calculation value [E] = precision encoder speed determination value [D] * 1024 + precision encoder position value ], Where the example of the absolute position calculation value [E] when the normal position value [F] is 990 is calculated as shown in Equation 3, and the position error value [G] And an error of 1024, which is the difference between the position value [F].

Table 2 shows the case where backlash is generated by 0.03 with respect to the value A1 of the wide-angle encoder 113 for one rotation of the precise encoder 112 in the theoretical position [B] of the wide- The absolute value of the absolute value of position [E] is also output as soon as the output value [C] of the wide-angle encoder 113 is output at this time. It is outputted in advance.

As described above, there are many problems when calculating the extended absolute position using two absolute value encoders. Accordingly, in order to solve the problem, a process of calculating the absolute absolute position through the following process is presented.

FIG. 17 is a conceptual diagram for measuring the number of revolutions of a precision encoder using a wide-angle encoder value according to an embodiment of the present invention. In the present invention, the value A1 of the wide-angle encoder 113 per revolution of the precision encoder 112 is used The step down upper limit value 308 and the down step band value 307 for the calculated rotation speed J_num N of the precision encoder 112 in the entire stroke and the step down upper limit value 308 and the down step band value 307 are calculated by the following equations 4 to 8 Lt; / RTI >

In order to calculate the number of revolutions of the precision encoder 112, the absolute position value ENC_POS calculated in Equation (1) is multiplied by the position value of the wide-angle encoder 113 per rotation of the precision encoder 112 A1 calculates the calculated rotation speed J_num of the integerized virtual precision encoder 112 of the precision encoder divided by the absolute position value ENC_POS and the calculated rotation speed J_num of the precision encoder 112 (J_remain) obtained by subtracting the value obtained by multiplying the position value A1 of the wide-angle encoder 113 by one rotation of the precision encoder 112 is calculated.

Equation (6) multiplies the calculated rotation speed (J_num) of the precision encoder 112 by the value A1 of the wide-angle encoder 113 per one revolution of the precise encoder 112, (Lower limit value J_min), which is a value obtained by subtracting a value obtained by multiplying the value A1 of the wide-range encoder 113 by a set value (assumed to be 25% in the present invention), and equation (7) (J_num) is multiplied by the value A1 of the wide-angle encoder 113 per one rotation of the precise encoder 112, and the set value of the value A1 of the wide-angle encoder 113 per one revolution of the precision encoder 112 (J_max), which is a value obtained by multiplying the precision encoder 112 calculation time (J_num) by the precision encoder 112, Is multiplied by the value A1 of the wide-angle encoder 113 and multiplied by the set value of the value A1 of the wide-angle encoder 113 per one rotation of the precision encoder 112 (assumed to be 25% in the present invention)The down step calculates the band value (J_min).

The method of calculating the number of revolutions of the precision encoder 112 using the value of the wide-angle encoder 113 based on these values is as follows. If the remaining value J_remain is larger than the set value (assuming 750 in the present invention) (112) Increase the calculated rotation speed (J_num) by one.

If the value of the wide encoder 113 is greater than or equal to the step down lower limit J_min and less than the down step band value J_down and the value of the precision encoder 112 is larger than the set value, .

18 is a precision encoder rotation speed determination table according to the present invention. The precision encoder 112 calculates a step-down lower limit value J_min, a step-down upper limit value J_max and a down step band value J_down calculated in FIG. The number of revolutions of the precision encoder 112 can be calculated based on the value of the wide-angle encoder 113 based on this value.

Here, A1 represents a value of the wide-angle encoder per one rotation of the precision encoder of Equation (2), N represents the number of rotations of the precision encoder, and int () represents a function of converting a real number to an integer. A is a constant in the range of 0 to 0.499,? Is a constant in the range of 0.5 to 0.999, and? Is a constant in the range of 0 to 0.499.

The precision encoder rotation number calculation table 420 shown in FIG. 18 is created based on the step-down lower limit value 306, the step-down upper limit value 308, and the down step band value 307 calculated through the above- The precision encoder rotation number calculation table 420 in Fig. 18 shows an example where a is set to 0.25, beta is set to 0.75, and gamma is set to 0.25.

FIG. 19 shows an example in which the above equations (4) to (8) are input to the Excel formula to perform consecutive calculations. When the common item REAL_POS is 990, the ENC1_OUT is 990 and the ENC2_POS is 11.000 And the POS_val of the general calculation is 2014, and the error Diff_norm is 1024.

At this time, the calculation of the present invention can be confirmed by calculating the equations (4) to (8) by using the Excel formula, and as a result, the PAT_POS is 990, and the error Diff_PAT is 0,

20 is a block diagram of a water level measuring controller according to an embodiment of the present invention.

20, the water level measuring controller 200 according to the present invention includes a precision encoder interface unit 204 to which a measurement signal is input from a precision encoder 112, And a microprocessor 201 for analyzing measurement signals of the precision encoder 112 and the wide-angle encoder 113 and calculating an absolute water level value. The level meter controller 200 includes a DC / DC converter 206 for supplying power, a FRAM memory 203 for storing various parameters and variables, a log data memory 213 for storing log data, An RS-232C communication unit 207 and an RS-485 communication unit 208 for communication with an external device, a liquid level level value output unit 209 for outputting a liquid level value to the outside, A limit signal output unit 210 for transmitting a limit signal to an external control device, an optical signal transmitting and receiving unit 211 for transmitting and receiving an optical signal, and an RF wireless transmitting and receiving unit 212 for transmitting and receiving data in a wireless manner.

A precision encoder 112 is connected to the precision encoder interface unit 204. The precision encoder interface unit 204 adjusts the level of a signal input from the precision encoder 112 and converts the signal into a binary number And inputs it to the microprocessor 201.

The wide-angle encoder interface unit 205 adjusts the level of a signal input from the wide-angle encoder 113 and converts the signal into a binary number And inputs it to the microprocessor 201.

The DC / DC converter 206 converts the external DC 24V power supply 150 to DC 5V and supplies the converted DC 5V power to the level measuring controller 200.

The microprocessor 201 analyzes the signals input through the precision encoder interface unit 204 and the wide-area encoder interface unit 205 to calculate the absolute position and the water level of the float 20 with the heater. A flash memory in which a program for analyzing measured signals from the precise encoder 112 and the wide-angle encoder 113 and calculating an absolute water level value is incorporated in the inside of the memory 201, and an SRAM in which various variables are stored. A USB port 202 is connected to the microprocessor 201. A notebook computer 160 is connected to the USB port 202 so that the notebook computer 160 and the microprocessor 201 can communicate with each other via a USB communication method. So that the notebook computer 160 can transmit an operation program to the microprocessor 201 or transfer parameter values to be set.

The FRAM memory 203 is a nonvolatile memory whose contents are not erased even when the power is turned off. The FRAM memory 203 stores a parameter value transmitted from the notebook computer 160 or an external device, or stores important parameter values. .

The RS-232C communication unit 207 is a circuit for communicating with an external device such as an external keyboard or an LCD & Key board 161, and inputs or modifies parameters through a keyboard connected to the RS-232C communication unit 207 And an operation state is displayed on the LCD & Key board 161. The keyboard and the keyboard also function to display a pressed state of the keyboard or a state of the apparatus and an alarm state through buzzer.

The RS-485 communication unit 208 is a communication circuit that performs a function of transmitting an absolute value or an operation state value to a wireless communication unit 165 such as a CDMA modem or an LTE modem according to a half-duplex communication method. (208) transmits the signal through a protocol such as MODBUS-RTU or MODBUS-ASCII or a specific PLC protocol specified in the corresponding parameter by CAN communication or CC-Link method. The RS-485 communication unit 208 also performs a function of exchanging signals by radio such as a CDMA modem, an LTE modem, WIFI, ZIGBEE, and transmitting / receiving data by installing a media converter on the outside.

The liquid level level value output unit 209 is a circuit for outputting the absolute level value calculated by the microprocessor 201 to the upper monitoring apparatus A 169. The liquid level level value output unit 209 outputs the liquid level value And converts the voltage into a voltage for driving a relay or an open collector element and outputs the voltage as a relay contact signal or an open collector output signal. The signal output through the liquid level value output unit 209 is a BCD signal when the value is 1, a binary signal when the value is 2, and a gray code when the value is 3 according to the value set in the Para_Output parameter.

The limit signal output unit 210 outputs Para_Pos1, which outputs a signal to the upper control device B 170 when the absolute position value reaches or exceeds the set position value 1, If it exceeds, there is Para_Pos2 which outputs a signal.

The optical signal transmitting and receiving unit 211 is a circuit for receiving or outputting signals of a glass optic fiber or a plastic optic fiber. The optical signal transmitting and receiving unit 211 transmits and receives data to and from the outside through an external optical signal converter 171 and an optical fiber, And functions to protect the device by blocking the incoming surge signal.

The RF wireless transmitting / receiving unit 212 wirelessly transmits the measured water level value to the main monitoring device because the water level measuring device is installed at a separate external location. The RF wireless transmitting and receiving unit 212 includes ZIGBEE , A WIFI or a 424 MHz wireless transmission method for data transmission, and transmits and receives data to and from an external device through an antenna 172 provided outside.

The log data memory 213 sequentially records the time stamp function indicating the time at each predetermined time and the water level data at that moment, the voltage of the solar light charging device for charging the power source through the sunlight, the door open state, The log data memory 213 carries out a multi-rotation recording function of recording from the beginning when the memory is fully written.

On the other hand, conventionally, the water level data is recorded in a paper recorder, and the manager visits the paper recorder to inspect the water level data to check the water level data. FIG. 21 is a flowchart showing the conventional method of measuring and collecting the dam level and the river level 1 shows an example of a system diagram of a single-station apparatus. First, the main terminal device 220 is a device that collects and manages data measured by the local terminal device 221 installed in each area. The local terminal device 221 receives data from a water level meter by a BCD method, A CDMA transmission device 222 and an LTE transmission device 222 that transmit the collected level data to the main terminal device 220 through a CDMA modem or an LED modem, And a paper recorder 225 for recording the water level value on the recording paper. The local terminal device 221 is driven by receiving power from the solar light charging device 226. The conventional method using such a paper recorder is accompanied by troublesome procedures for replacement of paper recording paper and cumbersome charging of ink and inspection of the manager's direct visit. On the other hand, in the present invention, the water level data and the status information of the local terminal device 221 are recorded in the log data memory 213 without using the paper recorder 225 and transmitted to the main terminal device 220. That is, when the level measuring controller 200 of the present invention receives the data transfer command from the remote main terminal 220, it extracts the data from the data stored in the log data memory 213 and transmits the data to the CDMA modem or the LTE It is possible to remotely check the status of the level data and the local terminal device without visiting the manager by transmitting the data to the main terminal device 220 through the wireless communication section 165 or the wireless signal transmission / do.

On the other hand, in the measurement of the dam level, a phenomenon may occur in which the water level fluctuates due to wind or waviness, or a large water level fluctuation occurs temporarily due to the start and stop of the generator, and a negative value is calculated in the discharge amount calculation. In the present invention, a method of calculating a water level value by applying a measured value to a digital filter in order to precisely measure the water level is used. Hereinafter, as an example of such a digital filter, An example in which a windowed-sinc filter, which is a digital filter having a plurality of filters, is applied will be described.

The signal processing method is divided into an analog filter method using a resistor, a capacitor, a coil, and a digital filter method implementing a filter function by a program of a processor. The digital filter method includes a method of calculating in a time domain and a method of calculating a frequency domain Frequency domain). The method of calculating the digital filter method in the time domain includes an IIR method (Infinite Impulse Response Methode) and an FIR method (Finite Impulse Response Methode). The frequency domain method uses a fast Fourier transform (FFT) A windowed-sinc filter calculation method which has a relatively small amount of calculation but is easy and has excellent filter performance has been applied in a method of extracting only a frequency component of a specific region from among a plurality of frequency domain components.

FIGS. 21, 22, and 23 show the characteristics of the windowed-sinc filter. The windowed sink filter has perfectly flat characteristics in the pass band, But cuts off all frequencies higher than the cut-off frequency.

As a result, if the cut-off frequency of the windowed-sinc filter is appropriately set, it becomes possible to measure an accurate water level calculation value by eliminating the water surface wave caused by the wind or the swell or the temporary large water level fluctuation. The transfer function (h [i]) of this filter is expressed by the following equation, where fc represents the cut-off frequency.

The equation using the window filter for implementing a more efficient filter function with respect to the cutoff frequency is expressed by the following equation.

Here, fc is the cut-off frequency, M is the filter kernel length, i is the sampling variable, 0? I? M, and K is the unity gain constant. The relationship between the band width BW for the cutoff frequency f _C and the number of filter samples M is expressed by the following equation.

FIG. 21 shows the characteristics of a filter having a windowed-sinc filter cut-off frequency F _C of 0.0015 Hz and a sampling number M of 600.

First, the value of H [i] / SUM obtained by dividing the value of H [i] by the sum of the values of H [i] / SUM is calculated by substituting the value of i from -300 to 300 in the above equation .

Since the unity gain constant (K) should be designed so that the output signal remains unchanged even when the frequency is zero, that is, even when the DC input signal is constant and the infinite time elapses, the sum of all the filter constants should be 1.0 Is a constant that divides the values of H [i] by a sum SUM (i.e., H [i] / SUM).

By multiplying the measured water level value by the coefficient of H [i] / SUM sequentially, and then integrating all of these values, the water level value at which the filter is applied can be obtained.

(A) of Figure 22 are simplified to show the value calculated by substituting the value of i to _{sin (2π · f c · i} ) from -300 to 300 in the graph, (b) is a final H rough a set of calculated [ i] / SUM is displayed in a graph.

FIG. 23 is an example of simulating a case where the water surface shakes virtually in order to test a characteristic of a window deck filter to be applied. In this case, assuming that the water surface is a small wave due to wind, three signals having different periods and amplitudes (Pd) of two positive (+) direction and two (Pd) negative (-) directions were assumed assuming that the generator started and suddenly fluctuates suddenly or doubled. , The water level value to be tested (input_val) is expressed by the following equation.

In FIG. 22, the operation result of the windowed-sinc filter is denoted by 'SINC filter output' and the operation result of the IIR filter is denoted by 'IIR average value' as another operation example.

In more detail, simulation was performed assuming that the water level fluctuates frequently due to wind and swell, and that a large disturbance of 20 cm due to the start and stop of the generator occurs for 5 seconds. When the window deck filter is applied, It is possible to calculate a very stable water level value having a water level variation of only 3 cm.

As described above, the water level measuring apparatus according to the present invention calculates the absolute position of the float 20 moving according to the water level change through the absolute displacement meter 100 and the water level controller 200, and measures the absolute water level . In addition, by applying the measured value to a windowed-sinc filter, which is a digital filter, it is possible to calculate a stable water level value even when the water level is suddenly changed.

It is to be understood that the present invention is not limited to the above-described embodiment, and that various modifications and changes may be made by those skilled in the art without departing from the spirit and scope of the appended claims. Of course, can be achieved.

10: Water level meter 20: Built-in heater float
21: heater 22: thermostat
23: lid 24: oil ring
25: terminal block 30: timing belt
31: Steel wire core 32: (+) Power line
33: (-) Power line 35: Belt fixing plate
36: Non-slip groove 37: Link device
40: timing pulley 41: timing pulley body
42: guide plate 43: guide plate fixing screw
45: Belt pressing bearing 46: Freezing heater
50: counterweight 55: roller
60: power supply unit 70: heater power pulley
71: Bearing 75: Heater power line
80: Power supply roller
100: absolute displacement meter 103: bearing
104: rotating shaft 105: rotating shaft gear
106: reduction gear 107a: first gear
107b: second gear 107c: third gear
112: precision encoder 113: wide-angle encoder
150: DC 24V power supply 160: Laptop computer
161: LCD & Key board 162: Coupling
163: Bearing support 165:
169: upper monitoring device A 170: upper control device B
171: Optical signal conversion device 172: Antenna
200: liquid level measurement controller 201: microprocessor
202: USB port 203: FRAM memory
204: Precision encoder interface unit 205: Wide encoder interface unit
206: DC / DC converter 207: RS-232C communication unit
208: RS-485 communication unit 209: liquid level level value output unit
210: limit signal output unit 211: optical signal transmission /
212: RF radio transmitting /

Claims (13)

A float 20 which floats on the water surface and moves up and down in accordance with the variation of the water level and a timing pulley 40 which converts the up and down movement amounts of the float 20, And a gauge 10 for calculating an absolute position value of the float 20 by receiving the rotation amount of the timing pulley 40 and calculating a water level value according to the absolute position of the calculated float 20, A water level measuring apparatus comprising:
The vertical movement amount of the float 20 is transmitted to the timing pulley 40 through the timing belt 30 having a plurality of steel wire cores 31 and is converted into a rotation amount, A slip prevention groove 36 is formed in the belt fixing plate 35 so that the timing belt 30 is fixed to the link device 37. [ The surface of the timing belt 30 is protruded and fixed to the slip prevention groove 36 when it is coupled to the link device 37 via the belt fixing plate 35,
The float 20 is supplied with power from a power supply unit 60 installed on the ground with a heater 21 built therein and is driven by one end of the float 20 to be connected to the upper portion of the float 20, The other end of the timing belt 30 is fixed to a power supply unit 60 provided on the ground via a roller 55. A counterweight 50 is coupled to a lower end of the roller 55, To tension the timing belt 30,
A heater power line 75 is connected to the power supply unit 60 and the heater power line 75 is connected to the power supply unit 60 via a heater power pulley 70 formed on a side surface of the timing pulley 40, A rotation bearing 71 is coupled to a center shaft of the heater power pulley 70 so that the rotation of the heater power pulley 70 is transmitted to the rotation of the timing pulley 40 Wherein the water level measuring device is configured to prevent the water level from being influenced.
The method according to claim 1,
In the timing pulley 40 receiving the up-and-down movement amount of the float 20 from the timing belt 30,
A timing pulley body 41 coupled to the timing pulley body 41 so as to prevent the timing belt 30 from slipping when engaged with the timing belt 30, And a guide plate (42) for guiding the flow of the water.
delete delete delete delete delete delete delete delete The method according to claim 1,
The level gauge 10 is coupled to a rotating shaft 104 that receives the rotation of the timing pulley 40 through a coupling 162 and measures a value corresponding to a rotation angle of the rotation shaft 104, A decelerating gear 106 composed of a plurality of gears for decelerating the rotational speed of the rotating shaft in engagement with the gear 105 formed on the rotating shaft 104; An absolute displacement gauge 100 provided on a shaft of a gear installed at the last stage and equipped with a wide-angle encoder 113 which is an absolute encoder for wide-range measurement that measures and outputs a value according to a decelerated rotation angle; The absolute position value of the float 20 is analyzed by analyzing the output values of the precision encoder 112 and the wide angle encoder 113 of the absolute displacement gauge 100 and the water level value according to the absolute position of the calculated float 20 is calculated And a water level measurement controller (200)
The water level measuring controller 200 is provided with a log data memory 213 for sequentially recording the time stamp indicating the time at each set time and the water level data at that moment, the voltage of the charging device, and the door open state in the memory, When the data transmission command is received from the main terminal 220, the data is extracted from the data stored in the log data memory 213 and transmitted to the main terminal 220 through the CDMA modem or LET modem or the radio signal transmission / And transmits the measurement result to the level measuring device. delete delete

Images