KR20000009978A - Device for monitoring filter of water purifier - Google Patents

Abstract

PURPOSE: A monitoring device for a filter of a water purifier is provided to supply a simple structure and to contain a reverse osmotic pressure typed filter unit. CONSTITUTION: A device for monitoring a filter of a water purifier comprises: an inflow pipe and a discharge pipe being connected to an inflow aperture(10) and to a discharge aperture(20) of a filter unit for forming a flowing passage of a raw water and a treated water; a source water detecting electrode and a treated water detecting electrode(50) being installed by penetrating the pipe walls of the inflow pipe and the discharge pipe; a common electrode(40) being installed by penetrating one of the pipe walls of the inflow pipe and the discharge pipe between the filter unit and on the electrodes; and a monitor circuit evaluating electric conduction rates of the source water and the treated water by using the electric signals from the three electrodes as standards.

Description

Filter monitoring device of water purifier

The present invention relates to a filter monitoring device for a water purifier, and more particularly, to a filter monitoring device for a water purifier using a reverse osmosis filter.

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.

Figure 1 shows a block diagram of a conventional water purifier monitoring device using a reverse osmosis filter. As shown in FIG. 1, a conventional water purifier has a filter unit including a reverse osmosis filter (ROF). An inlet pipe 1 through which unpurified water (hereinafter referred to as raw water) flows into the inlet of the filter unit. In addition, an outlet pipe 2 through which water (hereinafter referred to as treated water) purified by a filter flows out is connected to an outlet of the filter unit.

The inlet pipe 1 is provided with a pair of raw water detection electrodes 3 and 4 through the wall of the inlet pipe, and the outlet pipe 2 penetrates the wall with a pair of treated water detection electrodes ( 5 and 6) are installed. These electrodes are each connected to a monitoring circuit that determines the state of the filter. The monitoring circuit is connected to an indicator that visually or audibly informs the user of the condition of the filter.

By such a configuration, the monitoring apparatus of the conventional water purifier filter operates as follows.

Raw water flows in through the inflow pipe 1 and is purified by the filter ROF, and then flows out through the outflow pipe 2. At this time, the electrical conductivity of the raw water and the treated water, that is, the electrical resistance, is reduced by the raw water detection electrodes 3 and 4 and the treated water detection electrodes 5 and 6 provided in the inlet pipe 1 and the outlet pipe 2. Is measured.

Here, the electrical conductivity of the raw water and the electrical conductivity of the treated water vary depending on the distance between the electrodes to be measured, so to be comparable, it is necessary to make the distance between the raw water detection electrodes and the treated water detection electrodes the same. is average.

The electrical conductivity signals of the raw water and the treated water measured in this way are compared and judged in the monitoring circuit to determine the state of the filter, that is, whether the filter capacity is exhausted. The signal indicative of the filter state determined by the monitoring circuit is input to the display unit.

According to the applied signal, for example, the green lamp is turned on when the state of the filter is normal, and the state of the filter can no longer be purified, that is, the state where the water purification capacity is depleted and red when the replacement is necessary. As the lamp turns on, a warning buzzer will sound.

In the monitoring apparatus of the conventional water purifier filter, in order to measure the electrical conductivity of the raw water and the treated water, a pair of electrodes respectively provided in the inlet pipe 1 and the outlet pipe 2 was used, which was recognized as essential.

Accordingly, an object of the present invention is to provide a filter monitoring device of a water purifier having a simple structure and low cost.

1 is a block diagram of a monitoring apparatus of a conventional water filter;

2 is a block diagram of a monitoring device for a water filter of the present invention;

Figure 3 shows a schematic diagram of the monitoring device of the water filter of the present invention.

In order to achieve the above object, the present invention provides a filter monitoring device for a water purifier having a filter unit, the inlet and outlet pipes connected to the inlet and outlet of the filter unit, respectively, to form a flow passage of raw water and treated water; And a raw water detection electrode and a treated water detection electrode respectively installed through the pipe walls of the inflow pipe and the outflow pipe, and the pipe wall of any one of the inflow pipe and the outflow pipe between any one of the two electrodes and the filter unit. And a monitor circuit for evaluating the electrical conductivity of the raw water and the treated water based on the electrical signals from the three electrodes, and a display unit for displaying the evaluation result by the monitor circuit.

Here, the common electrode is preferably installed in the inlet pipe.

The present invention also provides a filter monitoring method for a water purifier having a reverse osmosis filter unit and an inlet tube and an outlet tube connected to inlets and outlets of the filter unit, respectively, to form flow paths of raw water and treated water. Measuring the conductivity of the raw water and the conductivity of the treated water using the raw water detection electrode and the treated water detection electrode installed in each of the inflow pipe and the outflow pipe, and the common electrode provided in any one of the inflow pipe and the outflow pipe; And evaluating the filtration performance of the filter unit based on both conductivity.

Here, it is preferable to further include the step of displaying the filtration performance of the filter unit evaluated.

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

2 shows a block diagram of a filter monitoring device of the water purifier of the present invention, and FIG. 3 schematically shows a device according to the invention. As shown in Figures 2 and 3, the water filter filter monitoring apparatus of the present invention has a filter unit including a filter, such as a reverse osmosis filter (ROF). An inlet pipe 10, which is a passage through which untreated raw water flows, is connected to the filter unit through a connection pipe 11. In addition, an outflow pipe 20, which is a passage through which the treated water treated by the filter flows out, is connected to the filter unit via a connection pipe 21.

On the inlet pipe 10, a raw water detection electrode 30 is installed through the inlet pipe 10. In addition, the treated water detection electrode 50 is provided on the outlet pipe 20 through the outlet pipe 20. On the inlet pipe 10, a common electrode 40 is provided between the raw water detection electrode 30 and the inlet of the filter unit.

Three electrodes provided on the inlet tube 10 and the outlet tube 20 are connected to a monitoring circuit that determines the state of the filter, that is, whether the filter capability is exhausted. The monitoring circuit is connected to a display unit that visually or audibly informs the user of the state of the filter.

With this configuration, the filter monitoring device of the water purifier according to the present invention operates as follows.

When raw water is not processed through the inlet pipe 10 to the reverse osmosis filter (ROF) of the filter unit, the raw water is purified by the reverse osmosis action. The treated water purified by the filter flows out through the outflow pipe 20.

At this time, the electrical conductivity of the raw water and the treated water is measured by the raw water detection electrode 30, the common electrode 40, and the treated water detection electrode 50 provided on the inflow pipe 10 and the outflow pipe 20. Here, the electrical conductivity of the raw water is measured between the raw water detection electrode 30 and the common electrode 40. In addition, the electrical conductivity of the treated water is measured between the treated water detection electrode 50 and the common electrode 40.

However, the electrical conductivity of the treated water cannot be directly measured by the dimension detection electrode 50 and the common electrode 40. This is because the common electrode 40 is provided on the inlet pipe 10 between the raw water detection electrode 30 and the inlet of the filter unit, and includes other elements.

Since conductivity is measured between the common electrode 40 and the filter ROF, the conductivity measured between the treated water detection electrode 50 and the common electrode 40 includes the conductivity of the raw water. In addition, the distance between the filter ROF and the treated water detection electrode 50 is different from the distance between the raw water detection electrode 30 and the common electrode 40. Therefore, in order to calculate the electrical conductivity of the treated water, a correction process is necessary in view of the above points.

That is, since the inverse of the electrical conductivity is the electrical resistance, the resistance is explained based on the resistance. The raw water between the common electrode 40 and the filter ROF is measured in the resistance measured between the treated water detection electrode 30 and the common electrode 40. By subtracting the resistance and converting the result value into the distance between the raw water detection electrode 30 and the common electrode 40, a comparable, purely treated water resistance is obtained.

Therefore, before the resistance of the treated water measured to the monitoring circuit is input, the resistance value is corrected by the correction circuit to the resistance of the actual treated water. A correction circuit, that is, a circuit for correcting the resistance measured between the common electrode 40 and the treated water detection electrode 50 with the resistance of comparable pure treated water, can be simply configured as described above.

The resistance of the raw water and the corrected treated water are thus input to the monitoring circuit. The monitoring circuit then compares and judges these and outputs a signal indicating the state of the filter to the display unit. The display unit visually or audibly displays the state of the filter according to the signal of the monitoring circuit. For example, the display unit emits a green lamp when the filter has the filter capability and is in a normal state, and emits a red lamp when the filter is exhausted and needs to be replaced, and at the same time emits a warning buzzer. Can be configured.

In the above, the common electrode is provided between the raw water detection electrode 30 and the inlet of the filter unit, but may be provided between the outlet of the filter unit and the treated water detection electrode 50.

As described above, the present invention can contribute to cost reduction by simplifying the structure of the device by configuring the filter monitoring device of the water purifier using three electrodes.

Claims (4)

In the filter monitoring device for a water purifier having a reverse osmosis type filter unit, An inlet pipe and an outlet pipe connected to an inlet and an outlet of the filter unit, respectively, to form a distribution passage between raw water and treated water; A raw water detection electrode and a treated water detection electrode respectively installed through the pipe walls of the inflow pipe and the outflow pipe; A common electrode installed between any one of the two electrodes and the filter unit through a pipe wall of any one of the inflow pipe and the outflow pipe; A monitor circuit for evaluating the electrical conductivity of raw water and treated water based on the electrical signals from the three electrodes; And a display unit for displaying an evaluation result by the monitor circuit. The method of claim 1, The common electrode is a filter monitoring device of the water purifier, characterized in that installed in the inlet pipe. In the filter monitoring method of the water purifier having a reverse osmosis filter unit, and an inlet pipe and an outlet pipe connected to the inlet and outlet of the filter unit, respectively, to form a flow passage of raw water and treated water, Measuring the conductivity of the raw water and the conductivity of the treated water using the raw water detection electrode and the treated water detection electrode installed on each of the inflow pipe and the outflow pipe, and the common electrode provided on any one of the inflow pipe and the outflow pipe; And evaluating the filtration performance of the filter unit based on the amount of conductivity. The method of claim 3, The filter monitoring method of the water purifier characterized in that it further comprises the step of displaying the filtration performance of the filter unit evaluated.