KR0159657B1 - High and low speed cofiltration water purifier - Google Patents

Abstract

The present invention can provide a rapid and slow combined water purifier using a combination of rapid filtration of fast water purification and slow filtration with high water purification effect to be used as a household water purifier or industrial water purifier to provide a high water purification speed and high water purification effect. The purpose is to make it possible.

The present invention is to be first supplied with water through a hose connected from the faucet, to support the bottom of the tank and the support provided with an installation space for accommodating the instrument therein, and is located in the installation space of the support The storage space is formed inside the empty cross-sectional shape, and the water is passed through a primary filtration group having multiple stages of filtration group and a water supply shutoff valve for blocking or supplying water passing through the primary filtration group. It is a flow rate control valve that regulates the amount of water, and adjusts the amount of water to an appropriate amount. Passed through the secondary filtration group to be filtered, and the secondary filtration group is filled while falling into the empty storage space and the upper portion of the storage space It is a water level control sensor that measures the full amount of water to prevent the overflow of water, and includes a water tank equipped with a faucet valve for discharging the filled water in the storage space.

Description

Rapid, slow merge water purifier

1 is a block diagram according to the present invention.

2 is a perspective view showing an embodiment according to the present invention.

3 is a cross-sectional view showing an embodiment according to the present invention.

4 is a control circuit diagram of an embodiment according to the present invention.

* Explanation of symbols for the main parts of the drawings

10: tank 11: storage space

12: faucet 20: support

21: installation space 30: primary filtration group

31 ceramic filter 32 activated carbon filter

33: UF filter 34: connection hose

35: connection hose 37: water valve connection adapter

38: supply hose 39: nozzle

40: primary storage container 41: air valve

50: secondary filtration group 51: ceramic filter

52: water filter 53: ion ceramic

54: ceramic container 60: magnet set

61: water supply shutoff valve 62: flow rate control valve

63: level control sensor 64: control device

65: electric code

The present invention relates to a water purifier, and in particular, rapid filtration (急速 濾過 or forced filtration) and slow filtration (緩速 濾過 or natural filtration) to be performed at the same time, by using a rapid filtration and slow filtration method to extend the life of the filter medium The present invention relates to a rapid and slow merging water purifier to enhance the water purification effect, to be convenient to use, and to provide better drinking water quality.

Recently, due to the development of civilization, water pollution and environmental pollution are serious.

In addition, in the case of a water supply source, which is a source of drinking water, is polluted at the source, and a water supply pipe and an apartment supplying it to a home are contaminated with a storage tank, it is difficult to use tap water as drinking water.

First, let's take a look at the water treatment method of drinking water source, which is the source of drinking water. At the St.Gallen Municipal Water Treatment Plant in Switzerland, the water was purified by slow filtration from 1895 to 1940. The water purification effect was very good.

However, in 1949, when the demand for water increased and slow filtration could not be used, the rapid filtration system could be used to treat a large amount of water. .

Therefore, from 1951, the first filtration was carried out through a rapid filtration system, and then slow filtration was performed. When the slow filtration of the slow filtration system was also performed only 6 to 8 times a year, the two water purification methods were used in parallel. As a result of the removal of the suspended solids from the rapid filtration system, it was passed through the slow filtration system, so it was reduced twice a year and the life of the filter medium was not only longer but also the water quality was greatly improved. After filtration, even bacteria were almost eliminated.

As can be seen in Table 1), the water quality that passed the slow filtration after the rapid filtration was found to have enhanced the water purification effect.

These results have been confirmed in water purifiers.

Conventional water purifiers equipped with filters to purify water by filtration method are generally connected to a water pipe or faucet by means of forced rapid filtration (hydraulic filtration method), and water is supplied by gravity by pouring water into a water tank equipped with a filter. There are two types of natural filtration (slow filtration), which is filtered and filtered. First, the water purifier (forced filtration or rapid filtration) forcibly filtered by water pressure has the advantage of being able to quickly filter a large amount of water due to the rapid filtration speed, but the short life of the filter has a shortcoming. Short time has a problem that the water purification effect is low.

Next, the natural filtration water purifier (or slow filtration method) has a good water purification effect by removing most bacteria including small suspensions in the water because they slowly pass through the filter medium by natural gravity. The filtration time is not long enough to provide sufficient water, the life of the filter medium due to the suspension is shortened, there is a problem that frequent backwashing.

Therefore, in view of the above problems, the present invention allows the rapid and slow combined water purifier using a combination of rapid filtration with fast water purification and slow filtration with high water purification effect to be used as a household water purifier or an industrial water purifier. The purpose is to provide a high water purifier.

Another object of the present invention is that the water through the hose attached to the water pipe first through the rapid filtration filter is directly connected to the water supply tank equipped with a slow filtration filter so that the water in the water supply passage is slow filtered through the filter, Very good water quality is achieved, and the drawback of slow filtration is that it extends the life of the filter.

Still another object of the present invention is a water supply shutoff valve for blocking or supplying water to the quick filtration filter unit for a more convenient use, a flow rate control valve for adjusting the amount of water, and a water level for adjusting the water level of the storage container. The control sensor and a control device for controlling all the above devices are configured to automatically supply water as much as water is used.

In order to achieve the object of the present invention, the present invention first supplies water through a hose connected from the faucet, supports the bottom of the tank, and has a support having an installation space for accommodating an instrument therein, and an installation space of the support. Located in the hollow cross-sectional shape, the storage space is formed inside the primary filtration group having a multi-stage filtration group in the storage space, and the water supply blocking to block or supply the water passing through the primary filtration group This is a flow rate control valve that regulates the amount of water through the valve, and adjusts the amount of water to an appropriate amount and supplies the reservoir through the hose connected to the upper part, and the pressure of the stored water while controlling the supply of water with the water level control sensor on the upper part of the storage container. Due to the natural filtration secondary filter group, and passed through the secondary filter group falls into the empty storage space The level control sensor, which fills the top of the storage space and measures the full water level, prevents the water from overflowing and includes a water tank with a faucet valve to drain the filled water out of the storage space.

When described in detail by the preferred embodiment as shown in the accompanying drawings, the present invention as follows.

1 is a principle configuration to show the whole of the present invention, the water tank 10 is a rapid filtration system built in the water purifier lower part 21 through the connection hose 34 in the water valve 37 (急速 濾過 方式) Phosphorus primary filtration tube 30; An upper storage container 40 for storing water in the upper part through the primary filtration group 30; After the water is primarily stored in the upper storage container 40, the water is filtered through a secondary filtration group 50, which is a natural filtration method, so that the user can ingest the water.

2 and 3 illustrate one embodiment of the present invention, and are shown in perspective and longitudinal cross-sectional views.

As shown in FIG. 2 and FIG. 3, the water tank 10 has a support 20 at its lower portion, and a water storage space 11 is formed in the hollowed-out and hollow interior so that purified water can be filled. By discharging the water by the operation of the faucet valve 12 installed in communication with this, the user can ingest the purified water.

Glass and ceramic materials were selected as the material of this water tank 10, and the taste of water was increased by the far-infrared radiation emitted from this ceramic.

The support 20 is to support the water tank 10 from the bottom to support the installation space 21 is formed so as to accommodate a variety of mechanisms inside the ABS resin excellent in strength.

The primary filtration group 30 installed in the installation space 21 is connected to the water valve 37 and the connection hose 34 so that the water supply through the multi-stage filter media by hydraulic pressure is forced filtration (= rapid filtration). It is.

The primary filtration group 30 is composed of a ceramic filter 31, an activated carbon filter 32, an UF filter and a membrane filter 33, and the unit filters are connected to the inlet and the outlet through a connection hose 35, respectively. The water is passed through and filtered in sequence.

In this case, the order of the filters may be changed, and includes a general 'R / O system'.

The tip of the hose 34 is preferably provided with an adapter 37 for connecting to the water valve.

Shut-off valve 61 to block the water supply between the ceramic filter 31 and the activated carbon filter 32 before the tap water passes through the primary filtration group 30 through the connection hose 34 in the water valve 37 and Connect the flow rate control valve 62 to control the amount of water, and then to be supplied to the primary storage container 40 through the hose 38 that passes through the primary filtration group 30 and connected to the upper container. . The bottom surface of the primary storage container 40 is opened in communication with the water tank 10 so that the contained water can fall, by installing a secondary filtration group 50 in this position natural water filtering method To be a second integer.

As such, the primary filtration group 30 for the automatic supplying device in the process of transferring the water, which is forcibly delivered to the water pressure by the primary filtration group 30, back to the storage container 40 is returned to the storage container 40. The water supply shutoff valve 61 and the flow rate control valve 62 are installed between the ceramic filter 31 and the activated carbon filter 32, and the water passing through the primary filtration group 30 is connected to the connection hose 38. As the water supply is automatically adjusted by the water level control sensor 63 stored in the primary storage container 40 and built in the storage container 40, the stored water drops to the bottom water tank 10 and the secondary filtration group ( 50 is passed through the filter is stored in the water tank 10 is configured to be applied by draining the water to the valve (12).

In this way, the water being forced by the primary filtration group 30 to be forcibly transported to the storage container 40 in the process of forced water back to the storage container 40 is connected to the end of the connection pipe 38 as a nozzle 39 and not shown inside. The permanent magnet 60 is not installed is to change the water molecules to magnetized water of hexagonal structure suitable for drinking by magnetizing when the water is moved.

Therefore, the taste of water is good and it is beneficial to health.

In addition, the nozzle 39 can select the injection amount of the water, the thickness of the water flow, the injection speed and the like to determine the purifying capacity by the secondary filtration group 50 and the transfer speed suitable for the magnetization effect by the permanent magnet. It can be.

And, it is preferable to install the air valve 41 on the upper portion of the storage container 40 so that the water level can be adjusted by adjusting the internal pressure.

The secondary filtration group 50 is to be installed in the connection portion of the storage container 40 and the water tank 10 to filter the water falling naturally.

The secondary filtration group 50 is composed of a ceramic filter 51, a water filter 52 using a natural geological layer structure, an ion ceramic 53, and a ceramic container 54 which surrounds them from outside to have a good taste. It will be made with fresh mineral water.

In this way, the water purifier of the present invention performs a more complete water purification function through the rapid (or forced) primary filtration group and the slow (or natural filtration) secondary filtration group, respectively. Can be changed to

In addition, the ability to increase the water purification speed is increased, there is an effect that the overall use capacity is improved.

4 shows a control circuit diagram for driving the water supply shutoff valve 61 of the present invention. The control circuit is driven by a rectifier circuit 1 for rectifying AC power to a DC power source and used as an operating power source for each circuit, and a power source of the rectifier circuit 1, and the water level control sensor 63 provides the water. A water supply terminal valve driving circuit 2 for operating the supply shutoff valve 61 and a compensation circuit 3 for stabilizing the operation of the water supply shutoff valve driving circuit 2.

The rectifier circuit 1 is rectified by a diode (D) connected to the primary side of the transformer (T) and connected to the secondary side of the transformer (T) and smoothed by the storage (R) and capacitor (C). You will get a stable DC power supply.

The water supply shutoff valve driving circuit 2 is connected to the water level control sensor 63 to the input side to detect a constant level of the water tank 10 by the resistance value, the diode (D) to the water level control sensor 63 The transistor TR is driven according to the amount of water in the water tank 10 detected by the water level control sensor 63 by connecting to the base of the transistor TR through the resistor R and the capacitor C). The relay RY for driving the water supply shutoff valve 63 is connected to the output of the transistor TR so that the water supply shutoff valve 63 is driven by the transistor TR.

The compensation circuit 3 connects the timer TM DP resistors R to R and the capacitors C and C, which are operated by using the output signal of the water supply cutoff driving circuit 2 as an input. The transistor TR is connected to the output of TM and then the relay RL is excited by the transistor TR to drive the water supply shutoff valve.

When the water level detected by the water level control sensor 63 installed in the water tank 10 is equal to or higher than a certain level, current is charged to the capacitor C so that the transistor TR is turned off so that the relay RY is not excited. That is, the water supply shutoff valve 61 is closed by the relay RY to block the water supply.

However, in contrast to the above, if the water sensed by the water level control sensor 63 is below a certain level, a bias is applied to the base of the transistor TR so that the transistor TR is turned on so that the relay RY is excited to activate the water supply shutoff valve 61. Is opened to supply water. In the above, the capacitor C connected to the base of the transistor TR has a constant delay time and a bias is applied to the base thereafter, so that the water tank is prevented from operating when the tank is shaken by an external impact so that the water does not overflow in the tank. It is to be able to delay the operation of the water supply shutoff valve (61).

If water is consumed in the tank 10 without external shock and water needs to be replenished, the capacitor TR conducts and the relay RY is excited when the capacitor C is discharged after charging (delay time). Accordingly, since the water supply shutoff valve 61 is opened, water is replenished in the water tank 10.

When the water is replenished in the water tank 10 to a predetermined level or more, the relay RY is not excited as described above, and the water supply shutoff valve 61 is closed to block the water supply. When the relay RY is excited, a low signal is applied to the terminal T of the timer TM connected to the collector of the transistor TR.

When the low signal is applied to the terminal T of the timer TM, the signal is delayed by a time constant by the resistor RR and the condenser C, and then a high signal is applied to the output terminal T of the timer TM so that the transistor TR is applied. Since the relay RL is excited by the operation, the water supply shutoff valve 61 is closed to block the water supply. Since the relay RL is turned off after a predetermined time delay (about 30 seconds) after the relay RL is turned off, the relay RL protects a leak or a solenoid.

The present invention as described above will be described according to an experimental example.

Experimental Example 1

Water quality and filter life through rapid filtration water purifier

(However, round ceramic size: outer diameter 55mm, inner diameter 30mm, height 140mm / pore 3-5μ

Activated carbon 18 × 50Mesh, results from 50g)

*) Raw water is obtained by diluting the normal bacterial culture in water without residual chlorine.

Experimental Example 2

Water quality and filter life through slow filtration

(However, round ceramic size: outer diameter 55mm, inner diameter 30mm, height 140mm / pore 20μ

Activated Carbon 18 × 50Mesh, Result of 100g)

*) Raw water is obtained by diluting the normal bacterial culture in water without residual chlorine.

Experimental Example 3

Water quality and filter life through rapid filtration through slow filtration

As shown in the above experiment, according to the configuration of the water purifier according to the present invention, the ability to purify suspended solids and various bacteria was increased, and the cleaning or replacement time of the filter was remarkably reduced. .

The water purifier configured as described above passes through the primary filtration group 30 of rapid (or forced) and the secondary filtration group 50 of slow (or natural filtration), respectively. It can be changed to be fresh and healthy.

In addition, the ability to increase the water purification speed is increased, there is an effect that the overall use capacity is improved.

Claims (8)

A water tank in which a storage space is formed in a hollow cross-sectional shape and a valve for extracting purified water filled in the storage space is installed; A support having an installation space for supporting a bottom of the tank and accommodating an instrument therein; A multistage primary filtration group located in an installation space of the support to force filtration of tap water supplied from a water valve to a hose by water pressure; A storage container installed in communication with the storage space of the tank and receiving the primary filtered water from the primary filtration group through a connecting pipe; The water level control sensor is installed inside the storage container, a rapid, slow merge water purifier, characterized in that it comprises a secondary filtration group to drop the water supplied to the storage space to filter. The rapid, slow merge water purifier according to claim 1, wherein the water tank is formed of a ceramic material. The rapid, slow merge water purifier of claim 1, wherein the primary filtration group comprises a ceramic filter, an activated carbon filter, an UF filter, and a membrane filter. The rapid and slow merge water purifier according to claim 1, wherein the storage container is formed of a transparent material. 2. The rapid and slow merge water purifier according to claim 1, wherein the secondary filtration group is composed of a ceramic filter, a water filter using a natural stratum structure, an ion ceramic, and a ceramic container surrounding them. 2. The rapid and slow combined water purifier of claim 1, wherein the primary filtration group comprises a water supply shutoff valve and a flow rate control valve. The water supply shutoff valve of claim 6, further comprising: a water supply shutoff valve driving circuit operated according to a signal sensed by the level control sensor; And a compensation circuit for compensating the operation of the water supply shutoff valve driving circuit. According to claim 1, wherein the water supply control valve installed in the water tank and the primary storage container, the water supply shutoff valve to control the amount of water by the flow rate control valve, characterized in that the timer device operates to automatically supply water Rapid, slow merge water purifier.