KR20000009977A - Circuit for monitoring and displaying of water purifier - Google Patents

Abstract

PURPOSE: A circuit for monitoring and displaying of a water purifier is provided to contain a reverse osmotic pressure filter and a carbon filter. CONSTITUTION: A water purifier can eliminate a contaminating material such as a metal ion and eliminate a fine floating particle not dissolved in water while monitoring the state of a carbon filter(CF). The water purifier includes:the carbon filter being connected to a reverse osmotic pressure filter(ROF) in series; a conduction rate measuring instrument for measuring the conduction rates of the water in the upper side and the lower side of the reverse osmotic pressure filter; a comparing instrument for comparing the both conduction rates; a time measuring unit for measuring the used period of the carbon filter; and a controlling unit for a displaying unit to display the replacing time of the carbon filter.

Description

Water Purifier Monitoring and Display Circuit

The present invention relates to a water purifier monitoring and display circuit, and more particularly, to a monitoring and display circuit of a water purifier having a reverse osmosis filter and a carbon filter together.

Reverse osmosis filtration water purifier is a water purifier to purify water by removing contaminants in the water using a reverse osmosis filter. By the way, in such a water purifier, the pores of the membrane used as the reverse osmosis filter are blocked by contaminants depending on the degree of use, and the purification ability of the membrane is reduced. Therefore, the reverse osmosis filter should be replaced at an appropriate time, and a system for informing such replacement osmosis filter is needed.

U.S. Patent No. 4,937,557 discloses a monitoring and display circuit of a reverse osmosis filter informing the replacement time of such a reverse osmosis filter. As a specific embodiment of the US patent, FIG. 1 shows a monitoring and displaying circuit of such a reverse osmosis filter.

As shown in FIG. 1, the reverse osmosis filter (ROF) is installed between the inlet pipe 12 through which the unpurified water enters and the outlet pipe 14 through which the purified water flows out if the reverse osmosis filter (ROF) works normally. It is. In addition, the drain osmosis part 16 is connected to the reverse osmosis filter ROF, and a portion of the water flowing into the reverse osmosis filter that does not pass through the reverse osmosis filter due to a difference in flow rate flows out through the drain connection part 16. do.

Inlet pipe 12 and outlet pipe 14 have stainless steel electrodes 18 and 20 for measuring the conductivity of unpurified water and stainless steel electrodes for measuring the conductivity of purified water, respectively, close to a reverse osmosis filter (ROF). The fields 22 and 24 are provided in the water flow direction at equal intervals. These electrodes function as conductivity cells.

In this circuit, a drive oscillator 26 including a Schmitt trigger inverter circuit 28 is provided. The Schmitt trigger inverter circuit 28 has a capacitor 30 connected between its input terminal and ground and a feedback resistor 32 connected in parallel with the inverter 28. The inverter circuit 28 thus configured generates a 1 KHz AC signal, which is coupled to the inverting input of the OP amplifier via a series connection with a capacitor 34 and a resistor 36 to reduce the voltage to a predetermined level. do.

The AC signal at the contact 40 is applied via the conductor 42 to the electrode 22 of the conductivity cell in the outlet pipe 14. The electrode 24 of the conductivity cell is connected to an inverting input terminal or a summing contact of another OP amplifier 44. Thus, the resistance between the electrodes 22 and 24 becomes the input resistance of the inverting OP amplifier 44.

The electrode 20 of the conductivity cell in the inlet pipe 12 is also connected to the summing contact 46 of the OP amplifier 44 and the other electrode 18 of the inlet side conductivity cell is opened by the conductor 48. It is connected to the output contact 50 of the amplifier 44. Thus, the resistance between the electrodes 18 and 20 becomes the feedback element of the OP amplifier 44.

Since the gain of the inverting OP amplifier 44 is proportional to the ratio of the feedback resistance to the input resistance, the gain is proportional to the ratio of the resistance of the unpurified influent to the resistance of the purified effluent. Thus, the 1.5 volt peak to peak signal supplied through the conductor 42 by the conditioning amplifier 38 is reduced by removal of the dissolved solids by the reverse osmosis filter (ROF).

The signal seen at the output terminal 50 can be estimated as a decrease in the water condition indication signal at the contact point 40, which is estimated as the rate of removal of the total dissolved solids of the reverse osmosis filter (ROF). The output terminal from the OP amplifier 44 seen at the contact point 50 is connected via the capacitor 52 to the non-inverting input of the OP amplifier 54. The OP amplifier 54 is characterized by a peak detector by a diode 56 connected between its output terminal and the inverting input terminal.

The voltage divider comprising resistors 58 and 60 with a holding capacitor 62 connected between ground and common contact 64 converts the voltage at contact 64 corresponding to the peak voltage measured at contact 50. Cause.

The 1.5 volt 1 KHz conditioned signal at contact 40 is applied to non-inverting input of OP amplifier 70 via conductor 66 and coupling capacitor 68. The OP amplifier 70 is also characterized by a peak detector equivalent to including the OP amplifier 54. Thus, the voltage signal developed at the contact 72 corresponds to the peak input voltage seen at the contact 40.

The resistance value of the resistors 74, 76, 77 and 79 connected in series will be selected by the switch 81 so that the output from the peak detector 70 will be reduced by the same ratio.

A comparator comprising an op amp 78 accepts the peak voltage developed at the contacts 64 and 72 as input, compares the two reduced AC signals and provides a logic level. The logic level is low if the rate of removal of total dissolved solids by the reverse osmosis filter is higher than required by the setting of the voltage separator comprising the resistors 74, 76, 77 and 79 by the switch 81. It will be high, and vice versa.

A pair of inverters 80 and 82 are connected between the output terminal of the comparator 78 and the contact point 84. The green LED diode 86 is connected between the DC voltage source (+ V) and the contact 84, and likewise the red LED diode 88 is connected between the same voltage source and the contact 84 via the inverter 90. .

Thus, if the removal rate provided by the reverse osmosis pressure is higher than the preset threshold voltage developed at the contact point 72, the green LED 86 is turned on; conversely, if the removal rate falls below the threshold value, the output from the comparator 78 Causes the red LED 88 to emit light.

The conventional water purifier having a reverse osmosis filter can be applied to remove contaminants such as solids dissolved in water, that is, metal ions, but has a limitation in that it is not suitable for removing fine particles suspended in water and suspended therein. .

Therefore, the present invention is not only suitable for removing contaminants such as metal ions, ie, metal ions that are dissolved in water, but also water purifiers, ie, reverse osmosis filters and carbon filters, which are suitable for removing fine particles that are not dissolved in water and are suspended. It is an object of the present invention to provide a water purifier monitoring and display circuit that indicates whether the reverse osmosis filter and the carbon filter of the water purifier are replaced.

1 is a conventional reverse osmosis filter type water purifier monitoring and display circuit,

2 shows a water purifier monitoring and display circuit of the present invention.

In order to achieve the above object, the present invention, in the water purifier having a reverse osmosis filter, at least one carbon filter connected in series with the reverse osmosis filter, and the conductivity of the water upstream and downstream of the reverse osmosis filter The conductivity of the reverse osmosis filter when the difference in conductivity from the conductivity measuring means for measuring, the comparing means for comparing the two conductivity, the time measuring part for measuring the period of use of the carbon filter, the display portion, and the comparing means is a predetermined value or more; It is determined that the replacement time, and when the measurement time of the time measuring unit is a predetermined time or more, characterized in that it comprises a control unit for determining that the replacement time of the carbon filter, and displays the fact on the display unit.

Here, the carbon filter is preferably disposed one each upstream and downstream of the reverse osmosis filter.

The conductivity measuring means further includes a first conductivity cell and a second conductivity cell which are respectively disposed upstream of the upstream carbon filter and downstream of the downstream carbon filter, each having a pair of electrodes immersed in water. do.

The time measuring unit may include an oscillator for generating a clock, and the controller determines that the carbon filter is to be replaced when the number of clocks is greater than or equal to a predetermined value.

The display unit may include a first display lamp indicating that both filters are in a normal state, a second display lamp indicating a state of the reverse osmosis filter, and a third display lamp indicating a state of the carbon filter. It is preferable.

In addition, during the initial electric application, the control unit preferably flashes the display lamps sequentially.

The control unit may control the display unit to blink at least when the second and third display lamps are displayed.

In addition, the present invention, in the monitoring and display method of a water purifier having a reverse osmosis filter, providing at least one carbon filter to be connected in series with the reverse osmosis filter, and upstream and downstream of the reverse osmosis filter In the conductivity measurement step of measuring the conductivity of the water, comparing the two conductivity, the step of measuring the use time of the carbon filter, and when the difference between the two conductivity is determined by the replacement time of the reverse osmosis filter is determined And determining the replacement time of the carbon filter when the measured use time of the carbon filter is more than a predetermined time, and displaying the state of each filter on the display unit.

Here, it is preferable that the carbon filter is provided one each upstream and downstream of the reverse osmosis filter.

The measuring the conductivity of the water may include: a first conductivity cell and a second electrode disposed upstream of the upstream carbon filter and downstream of the downstream carbon filter, each having a pair of electrodes immersed in water; It is preferably carried out by conductivity measuring means comprising a conductivity cell.

In addition, the display step indicates that both filters are in a normal state by a first display lamp, displays a state of the reverse osmosis filter by a second display lamp, and displays a state of the carbon filter by a third display lamp. It is preferable.

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

2 shows a water purifier monitoring and display circuit according to the invention. As shown in FIG. 2, the carbon filter CF is provided between the reverse osmosis filter ROF and the conductivity cell provided in the inlet pipe. Similarly, the carbon filter CF is provided between the reverse osmosis filter ROF and the conductivity cell provided in the outlet pipe.

Part A of FIG. 2 is the same as that of the circuit of FIG. 1 except that a carbon filter is provided on both sides of the reverse osmosis filter. Therefore, since the description of the A part circuit is the same as the above-described prior art, it is omitted here.

The present invention, unlike the prior art, using a carbon filter with a reverse osmosis filter in the circuit of the water purifier for removing not only the solids that are dissolved in water, that is, contaminants such as metal ions, but also fine particles not dissolved in water and suspended. In the present invention, not only the replacement time of the reverse osmosis filter but also the replacement time of the carbon filter to be used together is processed and displayed in the same circuit.

The logic level produced by the comparator comprising the op amp 178 is such that the rate of removal of total dissolved solids by the reverse osmosis filter includes the voltage separators comprising the resistors 174, 176, 177 and 179 by the switch 181. It goes low if it is higher than required by the setting, and goes high if it is vice versa.

Such a logic signal is input to the MICOM as an input signal. One terminal of the microcomputer is grounded, the other terminal is connected to a voltage source (+ Vcc) through a resistor (R), and a capacitor (C3) is connected between both terminals.

The microcomputer has an oscillator Osc connected in series with capacitors C1 and C2.

In addition, the microcomputer is connected to the base of the transistor through each of the resistors R1, R2 and R3. The cathodes of the diodes L1, L2, and L3 are connected to the collectors of the transistors, respectively, and the anodes of the diodes L1, L2, and L3 are connected to the voltage source + Vdd through a common contact. The emitters of each transistor are connected to ground, and each transistor is connected in parallel to each other.

By such a configuration, the logic signal generated by the OP amplifier 78 which is a comparator is input to the microcomputer. When the logic signal is a low value indicating that the reverse osmosis filter operates normally, a high state signal is applied to the base of the transistor T1 to which the resistor R1 is connected by a microcomputer. Then, the transistor T1 becomes conductive, and current flows from the voltage source + Vdd to the ground through the green diode L1 and the transistor T1 so that the green diode L1 emits light. Thus, the user will recognize that the reverse osmosis filter is operating normally.

At this time, a low state signal is applied to the bases of the other transistors T2 and T3. Therefore, since the transistors T2 and T3 are not conductive, the red diode L2 and the carbon filter display diode L3 do not emit light.

Similarly, when the logic signal input to the microcomputer is a high value indicating that the reverse osmosis filter does not operate normally, the high signal is applied to the base of the transistor T2 to which the resistor R2 is connected by the microcomputer. Then, the transistor T2 becomes conductive, and current flows from the voltage source + Vdd to the ground through the red diode L2 and the transistor T2 so that the red diode L2 emits light. Therefore, the user recognizes that the reverse osmosis filter does not operate normally and replaces the filter.

At this time, similarly, a low state signal is applied to the bases of the other transistors T1 and T3. Therefore, since the transistors T1 and T3 are not conductive, the green diode L1 and the carbon filter display diode L3 do not emit light.

On the other hand, the clock is generated by the oscillator installed in the microcomputer. When the generated clock is accumulated in an accumulator (not shown) in the microcomputer and its value reaches a predetermined value, the microcomputer generates a high state signal at the base of the transistor T3 to which the resistor R3 is connected. As a result, the transistor T3 conducts and the diode L3 emits light. Thus, the user recognizes that the carbon filter should be replaced.

At this time, as described above, the other transistors T2 and T3 do not conduct.

Since the use period of the carbon filter is typically about 6 months, the carbon filter can be replaced by setting to operate as described above when the actual use period is 6 months after the installation of the carbon filter.

When the diodes L1, L2, and L3 emit light, the user's attention can be reliably aroused by causing the light to emit at predetermined cycles. In order to cause each diode to emit light at a predetermined period, the diode L1 is periodically cycled by periodically repeating a high state and a low state of a signal state applied to, for example, a base of the transistor T1 to which the resistor R1 is connected in the microcomputer. It can be made to emit light. At this time, it is good to make it blink at a frequency of 0.5 to 2 Hz.

In addition, each diode (L1, L2, and L3) is an important indicator of the condition of the reverse osmosis filter and carbon filter used in the water purifier, so if the diode is broken, it is necessary to continue to use the filter beyond the replacement time without knowing the fact. This results in people eating contaminated water. Therefore, in the present invention, when the initial power is applied or the user requests, it is preferable that the diodes L1, L2, and L3 flash sequentially to control the presence of a failure by the control of the microcomputer.

In addition to the display means composed of diodes, the present invention may further include an alarm means for audibly informing the timing of replacement of the filters.

As described above, the present invention relates to a water purifier monitoring and display circuit equipped with a carbon filter together with a reverse osmosis filter. As a result, not only the solids soluble in water, that is, contaminants such as metal ions can be removed, but also fine particles floating without being dissolved in water can be removed. In addition, it is possible to monitor not only the state of the reverse osmosis filter but also the state of the carbon filter at the same time, and to properly display the timing of replacing the filters.

Claims (11)

In a water purifier having a reverse osmosis filter, At least one carbon filter connected in series with the reverse osmosis filter; Conductivity measuring means for measuring the conductivity of water on the upstream and downstream sides of the reverse osmosis filter; Comparison means for comparing both conductivity; A time measuring unit for measuring the use period of the carbon filter; With display part, When the difference in conductivity from the comparison means is predetermined or more, it is determined that the reverse osmosis filter replacement time, and when the measurement time of the time measuring unit is more than the predetermined time is determined as the replacement time of the carbon filter, and displays the fact on the display unit Water purifier monitoring and display circuit including a control unit. The method of claim 1, And the carbon filter is disposed one each upstream and downstream of the reverse osmosis filter. The method of claim 2, Wherein said conductivity measuring means comprises a first conductivity cell and a second conductivity cell respectively disposed upstream of said upstream carbon filter and downstream of said downstream carbon filter, each having a pair of electrodes immersed in water. Water purifier monitoring and display circuit. The method of claim 1, The time measuring unit includes an oscillator for generating a clock, and the control unit monitors and displays the water purifier, characterized in that it is determined that the replacement time of the carbon filter when the number of clocks is more than a predetermined. The method of claim 1, The display unit may include a first display lamp indicating that both filters are in a normal state; A second display lamp displaying a state of the reverse osmosis filter; And a third display lamp for displaying a state of the carbon filter. The method of claim 5, The controller according to claim 1, wherein the control unit blinks the display lamps sequentially. The method of claim 5, And the control unit controls the at least one display unit to blink when the second and third display lamps are displayed. In the monitoring and display method of a water purifier having a reverse osmosis filter, Providing at least one carbon filter to be connected in series with the reverse osmosis filter; A conductivity measuring step of measuring conductivity of water at an upstream side and a downstream side of the reverse osmosis filter; Comparing the two conductivity, Measuring the use time of the carbon filter; Determining when the reverse osmosis filter is replaced when the difference between the two conductivity values is more than a predetermined value; Determining the replacement time of the carbon filter when the measured use time of the carbon filter is more than a predetermined time; Water purifier monitoring and display method comprising the step of displaying the status of each filter on the display. The method of claim 8, The carbon filter is a water purifier monitoring and display method, characterized in that each provided upstream and downstream of the reverse osmosis filter. The method of claim 9, Measuring the conductivity of the water, the first conductivity cell and the second conductivity cell respectively disposed upstream of the upstream carbon filter and downstream of the downstream carbon filter, each having a pair of electrodes immersed in water Water purifier monitoring and display method characterized in that performed by the conductivity measuring means comprising a. The method of claim 8, The displaying step may include displaying that both filters are in a normal state by a first display lamp, displaying a state of the reverse osmosis filter by a second display lamp, and displaying a state of the carbon filter by a third display lamp. Water purifier monitoring and display method.