CN216808976U - Electrolyzed water switch device based on ionized current detection water flow - Google Patents

Abstract

The utility model discloses an electrolyzed water switch device for detecting water flow based on ionization current, which comprises an ionization plate mechanism, an ionization plate driving mechanism, a first electrode mechanism, a second electrode mechanism, an ionization current detection mechanism, an electrolyzed water mechanism, an electrolysis switch mechanism, a control mechanism and a power supply mechanism, wherein the ionization plate mechanism is connected with the ionization plate driving mechanism; the ionization plate mechanism, the first electrode mechanism and the second electrode mechanism are all arranged in water to be detected, the ionization plate mechanism is electrically connected with the ionization plate driving mechanism, and the first electrode mechanism and the second electrode mechanism are respectively electrically connected with the ionization current detection mechanism; and the control end of the electrolysis switch mechanism, the ionization plate driving mechanism and the ionization current detection mechanism are respectively electrically connected with the control mechanism. The utility model can solve the problem that the existing electrolytic circuit is easy to burn out when being electrified, and has the advantages of low cost, strong reliability and convenient operation and use by customers.

Description

Electrolyzed water switch device based on ionized current detection water flow

Technical Field

The utility model relates to the field of dentistry, in particular to an electrolytic water switch device for detecting water flow based on ionization current.

Background

The dental integrated treatment chair is common equipment in dental diagnosis and treatment operations, the pollution of a waterway of a dental integrated treatment table is considered to be one of important ways for causing dental cross infection, and a method for intermittently and periodically or continuously disinfecting the waterway by using a chemical disinfectant, a bactericide or a cleaning agent can control a biological membrane and improve the water quality to a certain extent.

The method for generating hypochlorous acid by electrolysis is more convenient, and can quickly kill various bacteria, viruses, fungi and other microorganisms in a broad spectrum by depending on the oxidability of the hypochlorous acid, so that the biomembrane on the inner wall of the water channel is thoroughly clear. The hypochlorous acid generated by electrolysis is nontoxic and harmless to human body, can be completely degraded after sterilization, and has no residue, corrosion or pungent smell. The use of the electrolysis circuit has certain limitations, namely the electrolysis circuit can be electrified in flowing water, and the electrolysis circuit is easy to burn out when the electrolysis circuit is electrified in static water. Therefore, a device for identifying whether water flows in the waterway is necessary.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem of providing an electrolytic water switch device for detecting water flow based on ionization current, which can solve the problem that the existing electrolytic circuit is easy to burn out when being electrified and has the advantages of low cost, strong reliability and convenience for customers to operate and use.

In order to solve the technical problem, the utility model provides an electrolyzed water switch device for detecting water flow based on ionization current, which comprises an ionization plate mechanism, an ionization plate driving mechanism, a first electrode mechanism, a second electrode mechanism, an ionization current detection mechanism, an electrolyzed water mechanism, an electrolysis switch mechanism, a control mechanism and a power supply mechanism, wherein the ionization plate driving mechanism is connected with the first electrode mechanism; the ionization plate mechanism, the first electrode mechanism and the second electrode mechanism are all arranged in water to be detected, the ionization plate mechanism is electrically connected with the ionization plate driving mechanism, and the first electrode mechanism and the second electrode mechanism are respectively electrically connected with the ionization current detection mechanism; the control end of the electrolysis switch mechanism, the ionization plate driving mechanism and the ionization current detection mechanism are electrically connected with the control mechanism respectively, the input end of the electrolysis switch mechanism, the control mechanism, the ionization plate driving mechanism and the ionization current detection mechanism are electrically connected with the power supply mechanism, and the output end of the electrolysis switch mechanism is electrically connected with the water electrolysis mechanism.

Preferably, the ionization plate driving mechanism comprises a driving module, a first current limiting module, a second current limiting module, a third current limiting module and a first filtering module; the driving module is electrically connected with the ionization plate mechanism through the first current limiting module; the driving module is electrically connected with the power supply mechanism through a second current limiting module and is grounded through the second current limiting module and the first filtering module in sequence; the driving module is electrically connected with the control mechanism through a third current limiting module.

Preferably, the ionization current detection mechanism comprises a current detection module, a fourth current limiting module, a fifth current limiting module, a sixth current limiting module, a seventh current limiting module and a second filtering module; the first electrode mechanism and the second electrode mechanism are respectively and electrically connected with the current detection module through the fourth current limiting module and the fifth current limiting module; the current detection module is electrically connected with the power supply mechanism through a sixth current limiting module and is grounded through the sixth current limiting module and the second filtering module in sequence; the current detection module is electrically connected with the control mechanism through a seventh current limiting module.

Preferably, the electrolytic switching mechanism comprises a first switching module, an eighth current limiting module, a ninth current limiting module and a third filtering module; the output end of the first switch module is the output end of the electrolysis switch mechanism; one end of the eighth current limiting module is the input end of the electrolytic switching mechanism and is grounded through the third filtering module, and the other end of the eighth current limiting module is connected with the input end of the first switching module; one end of the ninth current limiting module is a control end of the electrolysis switching mechanism, and the other end of the ninth current limiting module is connected with the control end of the first switching module.

Preferably, the power supply mechanism comprises a first power supply module, a first voltage conversion module, a change-over switch module, a second power supply module, a second voltage conversion module, a charging switch module and a low-power detection module; the input end of the first voltage conversion module is electrically connected with the first power supply module, the output end of the first voltage conversion module is electrically connected with the control end and the output end of the change-over switch module and the input end of the charging switch module, the input end of the change-over switch module and one end of the low-power detection module are both electrically connected with the second power supply module, the control end of the charging switch module and the other end of the low-power detection module are respectively electrically connected with the control mechanism, the output end of the charging switch module is electrically connected with the charging end of the second power supply module, the input end of the second voltage conversion module is electrically connected with the output end of the change-over switch module, the input end of the electrolysis switch mechanism and the ionization plate driving mechanism, the output end of the second voltage conversion module is electrically connected with the ionization current detection mechanism and the control mechanism; the first voltage conversion module is a direct current-to-alternating current power adapter.

Preferably, the change-over switch module includes a first switch unit, a first current limiting unit, a second current limiting unit, a first filtering unit and a second filtering unit; one end of the first current limiting unit is a control end of the change-over switch module and is grounded through the first filtering unit, and the other end of the first current limiting unit is electrically connected with the control end of the first switch unit; one end of the second current limiting unit is the input end of the change-over switch module and is grounded through the second filtering unit, and the other end of the second current limiting unit is electrically connected with the input end of the first switch unit; the output end of the first switch unit is the output end of the change-over switch module.

Preferably, the charging switch module includes a second switch unit, a third current limiting unit, a fourth current limiting unit, a third filtering unit and a fourth filtering unit; one end of the third current limiting unit is a control end of the charging switch module, and the other end of the third current limiting unit is electrically connected with the control end of the second switch unit; one end of the fourth current limiting unit is the input end of the charging switch module and is grounded through the third filtering unit, and the other end of the fourth current limiting unit is electrically connected with the input end of the second switch unit; the output end of the second switch unit is the output end of the charging switch module and is grounded through the fourth filtering unit.

Preferably, the second voltage conversion module includes a voltage conversion unit, a fifth filtering unit and a sixth filtering unit; the input end of the voltage conversion unit is the input end of the second voltage conversion module and is grounded through the fifth filtering unit; the output end of the voltage conversion unit is the output end of the second voltage conversion module and is grounded through the sixth filtering unit.

Preferably, the electrolyzed water switching device for detecting water flow based on ionization current further comprises a warning mechanism, wherein the warning mechanism comprises an indicator lamp module, a loudspeaker module, a second switch module, a tenth current limiting module, an eleventh current limiting module and a fourth filtering module; the input end of the second switch module is electrically connected with the power supply mechanism through the tenth current-limiting module and is sequentially grounded through the tenth current-limiting module and the fourth filtering module, the control end of the second switch module is electrically connected with the control mechanism through the eleventh current-limiting module, the output end of the second switch module is grounded through the indicator lamp module, and the loudspeaker module is connected with the indicator lamp module in parallel.

Preferably, the electrolyzed water switching device for detecting water flow based on ionization current further comprises a wireless communication mechanism, and the wireless communication mechanism is electrically connected with the power supply mechanism and the control mechanism.

The beneficial effects of the implementation of the utility model are as follows:

according to the utility model, the ionization plate mechanism, the first electrode mechanism and the second electrode mechanism are all arranged in water to be detected, the ionization plate mechanism is electrically connected with the ionization plate driving mechanism, and the first electrode mechanism and the second electrode mechanism are respectively electrically connected with the ionization current detection mechanism; the control end of the electrolysis switch mechanism, the ionization plate driving mechanism and the ionization current detection mechanism are electrically connected with the control mechanism respectively, the input end of the electrolysis switch mechanism, the control mechanism, the ionization plate driving mechanism and the ionization current detection mechanism are electrically connected with the power supply mechanism, and the output end of the electrolysis switch mechanism is electrically connected with the water electrolysis mechanism.

The utility model can solve the problem that the existing electrolytic circuit is easy to burn out when being electrified, and has the advantages of low cost, strong reliability and convenient operation and use by customers; the flow state of water is monitored by the ionization plate mechanism, the ionization plate driving mechanism and the ionization current detection mechanism, and the control mechanism controls the switch of the electrolysis switch mechanism according to the flow state of the water, so that the running state of the water electrolysis mechanism is controlled.

Drawings

FIG. 1 is a schematic block diagram of an electrolytic water switching device for detecting water flow based on ionization current provided by the present invention;

FIG. 2 is a functional block diagram of an ionization plate drive mechanism provided by the present invention;

FIG. 3 is a functional block diagram of an ionization current detection mechanism provided by the present invention;

FIG. 4 is a functional block diagram of an electrolytic switching mechanism provided by the present invention;

FIG. 5 is a schematic structural diagram of a power supply mechanism provided by the present invention;

FIG. 6 is a functional block diagram of a diverter switch module provided by the present invention;

FIG. 7 is a functional block diagram of a charge switch module provided by the present invention;

FIG. 8 is a functional block diagram of a second voltage conversion module provided by the present invention;

fig. 9 is a functional block diagram of a warning mechanism provided by the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings. It is only noted that the utility model is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the utility model.

As shown in fig. 1, the present invention provides an electrolyzed water switching apparatus for detecting water flow based on ionization current, which includes an ionization plate mechanism 1, an ionization plate driving mechanism 2, a first electrode mechanism 7, a second electrode mechanism 8, an ionization current detection mechanism 3, an electrolyzed water mechanism 9, an electrolysis switching mechanism 4, a control mechanism 10 and a power supply mechanism 5; the ionization plate mechanism 1, the first electrode mechanism 7 and the second electrode mechanism 8 are all arranged in water to be detected, the ionization plate mechanism 1 is electrically connected with the ionization plate driving mechanism 2, and the first electrode mechanism 7 and the second electrode mechanism 8 are respectively electrically connected with the ionization current detection mechanism 3; electrolysis switching mechanism 4's control end, ionization plate actuating mechanism 2 and ionization current detection mechanism 3 respectively with control mechanism 10 electric connection, electrolysis switching mechanism 4's input, control mechanism 10, ionization plate actuating mechanism 2 and ionization current detection mechanism 3 all with power supply mechanism 5 electric connection, electrolysis switching mechanism 4's output with electrolysis water mechanism 9 electric connection.

It should be noted that the control mechanism 10 is a single chip, but is not limited thereto; the singlechip integrates a plurality of components such as an arithmetic unit, a controller, a memory, an input/output device and the like, and realizes a plurality of functions such as signal processing, data storage and the like. For example, an arithmetic unit includes a large number of comparison circuits, and can perform logical operation processing on a received signal instruction.

According to the utility model, the ionization plate mechanism 1, the first electrode mechanism 7 and the second electrode mechanism 8 are all arranged in water to be detected, the ionization plate mechanism 1 is electrically connected with the ionization plate driving mechanism 2, and the first electrode mechanism 7 and the second electrode mechanism 8 are respectively electrically connected with the ionization current detection mechanism 3; electrolysis switching mechanism 4's control end, ionization plate actuating mechanism 2 and ionization current detection mechanism 3 respectively with control mechanism 10 electric connection, electrolysis switching mechanism 4's input, control mechanism 10, ionization plate actuating mechanism 2 and ionization current detection mechanism 3 all with power supply mechanism 5 electric connection, electrolysis switching mechanism 4's output with electrolysis water mechanism 9 electric connection. The utility model can solve the problem that the existing electrolytic circuit is easy to burn out when being electrified, and has the advantages of low cost, strong reliability and convenient operation and use by customers; the flow state of water is monitored by the ionization plate mechanism 1, the ionization plate driving mechanism 2 and the ionization current detection mechanism 3, and the control mechanism controls the switch of the electrolysis switch mechanism according to the flow state of the water, so as to control the running state of the electrolysis water mechanism.

Specifically, with feedback from the ionization circuit, standing water and flowing water, will cause a change in the ionized current, thereby identifying. When the water is static, the current output by the ionization circuit is small; when water flows, the current output by the ionization circuit is larger. The utility model has lower price and cost, stronger reliability and convenient operation and use by customers.

As shown in fig. 2, the ionization plate driving mechanism 2 includes a driving module 21, a first current limiting module 22, a second current limiting module 23, a third current limiting module 24, and a first filtering module 25; the driving module 21 is electrically connected with the ionization plate mechanism 1 through the first current limiting module 22; the driving module 21 is electrically connected with the power supply mechanism 5 through a second current limiting module 23 and is grounded through the second current limiting module 23 and the first filtering module 25 in sequence; the driving module 21 is electrically connected to the control mechanism 10 through a third current limiting module 24.

It should be noted that, in this embodiment, the ionization plate mechanism is driven by the driving module 21, and current is limited by the first current limiting module 22, the second current limiting module 23, and the third current limiting module 24 to avoid burning out the driving module, and noise in the circuit is filtered by the first filtering module 25 to improve the stability of the circuit.

As shown in fig. 3, the ionization current detection mechanism 3 includes a current detection module 31, a fourth current limiting module 32, a fifth current limiting module 33, a sixth current limiting module 34, a seventh current limiting module 35, and a second filtering module 36; the first electrode mechanism 7 and the second electrode mechanism 8 are respectively and electrically connected with the current detection module 31 through the fourth current limiting module 32 and the fifth current limiting module 33; the current detection module 31 is electrically connected with the power supply mechanism 5 through a sixth current limiting module 34 and is grounded through the sixth current limiting module 34 and the second filtering module 36 in sequence; the current detection module 31 is electrically connected to the control mechanism 10 through a seventh current limiting module 35.

It should be noted that, in this embodiment, the current detection module 31 detects the magnitude of the ionization current, and the fourth current limiting module 32, the fifth current limiting module 33, the sixth current limiting module 34, and the seventh current limiting module 35 limit the current to avoid burning out the current detection module 31, and the second filtering module 36 filters noise in the circuit to improve the stability of the circuit.

As shown in fig. 4, the electrolysis switching mechanism 4 includes a first switching module 41, an eighth current limiting module 42, a ninth current limiting module 43, and a third filtering module 44; the output end of the first switch module 41 is the output end of the electrolysis switch mechanism 4; one end of the eighth current limiting module 42 is an input end of the electrolytic switching mechanism 4 and is grounded through the third filtering module 44, and the other end of the eighth current limiting module 42 is connected with an input end of the first switching module 41; one end of the ninth current limiting module 43 is a control end of the electrolysis switching mechanism 4, and the other end of the ninth current limiting module 43 is connected to the control end of the first switching module 41.

It should be noted that, in this embodiment, the on-off state of the electrolytic switching mechanism 4 is controlled by controlling the on-state of the first switching module 41, the eighth current limiting module 42 and the ninth current limiting module 43 are used to limit current to avoid burning out the first switching module 41, and meanwhile, the third filtering module 44 is used to filter noise in the circuit to improve the stability of the circuit.

As shown in fig. 5, the power supply mechanism 5 includes a first power supply module 51, a first voltage conversion module 52, a change-over switch module 53, a second power supply module 54, a second voltage conversion module 55, a charge switch module 56, and a low-power detection module 57; the input end of the first voltage conversion module 52 is electrically connected to the first power supply module 51, the output end of the first voltage conversion module 52 is electrically connected to the control end and the output end of the switch module 53 and the input end of the charging switch module 56, the input end of the switch module 53 and one end of the low-power detection module 57 are electrically connected to the second power supply module 54, the control end of the charging switch module 56 and the other end of the low-power detection module 57 are electrically connected to the control mechanism 10, respectively, the output end of the charging switch module 56 is electrically connected to the charging end of the second power supply module 54, the input end of the second voltage conversion module 55 is electrically connected to the output end of the switch module 53, the input end of the electrolytic switch mechanism 4 and the ionization plate driving mechanism 2, and the output end of the second voltage conversion module 55 is electrically connected to the ionization current detection mechanism 3 and the control mechanism 10 (ii) a The first voltage conversion module 52 is a dc-to-ac power adapter.

It should be noted that, in this embodiment, the first power supply module 51 is a commercial power supply system, and the second power supply module 54 is a storage battery device, but is not limited thereto; when a power failure (power failure of the first power supply module 51) occurs, the change-over switch module is turned on, the second power supply module supplies power to a subsequent mechanism through the second voltage conversion module, when the first power supply module 51 supplies power normally, the change-over switch module is turned off, and the first power supply module 51 supplies power to the subsequent mechanism sequentially through the first voltage conversion module and the second voltage conversion module, so that the influence of power failure can be avoided, and the stability of a product is improved; in addition, the low-power detection module monitors the residual electric quantity of the second power supply module in real time, when the residual electric quantity is smaller than the preset electric quantity, the charging switch module is turned on, and the first power supply module charges the second power supply module through the first voltage conversion module, so that the cruising ability of the second power supply module is guaranteed, and the stability of a product is improved.

As shown in fig. 6, the switch module 53 includes a first switch unit 531, a first current limiting unit 532, a second current limiting unit 533, a first filtering unit 534, and a second filtering unit 535; one end of the first current limiting unit 532 is a control end of the switch module 53 and is grounded through the first filtering unit 534, and the other end of the first current limiting unit 532 is electrically connected to the control end of the first switching unit 531; one end of the second current limiting unit 533 is an input end of the switch module 53 and is grounded through the second filtering unit 535, and the other end of the second current limiting unit 533 is electrically connected to the input end of the first switching unit 531; the output terminal of the first switch unit 531 is the output terminal of the change-over switch module 53.

It should be noted that, in this embodiment, the on-off state of the switch module is controlled by controlling the on-state of the first switch unit 531, the current is limited by the first current-limiting unit 532 and the second current-limiting unit 533 to avoid burning out the first switch unit 531, and noise in the circuit is filtered by the first filtering unit 534 and the second filtering unit 535 to improve the stability of the circuit.

As shown in fig. 7, the charging switch module 56 includes a second switch unit 561, a third current limiting unit 562, a fourth current limiting unit 563, a third filtering unit 564, and a fourth filtering unit 565; one end of the third current limiting unit 562 is a control end of the charging switch module 56, and the other end of the third current limiting unit 562 is electrically connected to a control end of the second switch unit 561; one end of the fourth current limiting unit 563 is an input end of the charging switch module 56 and is grounded through the third filtering unit 564, and the other end of the fourth current limiting unit 563 is electrically connected to an input end of the second switch unit 561; the output terminal of the second switch unit 561 is the output terminal of the charging switch module 56 and is grounded through the fourth filtering unit 565.

It should be noted that in this embodiment, the on-off state of the switch module is controlled by controlling the conducting state of the second switch unit 561, the current is limited by the third current limiting unit 562 and the fourth current limiting unit 563 to avoid burning the second switch unit 561, and noise in the circuit is filtered by the third filtering unit 564 and the fourth filtering unit 565 to improve the stability of the circuit.

As shown in fig. 8, the second voltage conversion module 55 includes a voltage conversion unit 551, a fifth filtering unit 552, and a sixth filtering unit 553; the input terminal of the voltage converting unit 551 is the input terminal of the second voltage converting module 55 and is grounded through the fifth filtering unit 552; the output terminal of the voltage converting unit 551 is the output terminal of the second voltage converting module 55 and is grounded through the sixth filtering unit 553.

In this embodiment, the voltage conversion unit converts the working voltage to obtain a working voltage suitable for each mechanism, and the fifth filtering unit 552 and the sixth filtering unit 553 filter noise in the circuit to improve the stability of power supply.

As shown in fig. 9, the electrolyzed water switching apparatus that detects water flow based on an ionization current further includes a warning mechanism (not labeled) that includes an indicator module 61, a speaker module 62, a second switch module 63, a tenth current limit module 64, an eleventh current limit module 65, and a fourth filter module 66; the input end of the second switch module 63 is electrically connected to the power supply mechanism 5 through the tenth current limiting module 64 and is grounded sequentially through the tenth current limiting module 64 and the fourth filtering module 66, the control end of the second switch module 63 is electrically connected to the control mechanism 10 through the eleventh current limiting module 65, the output end of the second switch module 63 is grounded through the indicator light module 61, and the speaker module 62 is connected in parallel to the indicator light module 61.

It should be noted that in this embodiment, the on state of the second switch module 63 is controlled to further control the operating states of the indicator light module 61 and the speaker module 62, the tenth current limiting module 64 and the eleventh current limiting module 65 are used for limiting the current to avoid burning out the indicator light module 61, the speaker module 62 and the second switch module 63, and meanwhile, the fourth filtering module 66 is used for filtering out noise in the circuit to improve the stability of the circuit. When the residual capacity monitored by the low-power detection module is less than the preset capacity for a long time, the second switch module is switched on and then the low-power indication is carried out by the indicator lamp module 61 and the loudspeaker module 62 to remind the user of carrying out timely replacement and maintenance.

Preferably, the electrolyzed water switching device for detecting water flow based on ionized current further comprises a wireless communication mechanism (not marked), and the wireless communication mechanism is electrically connected with the power supply mechanism and the control mechanism.

It should be noted that, in this embodiment, a user may establish a communication connection with the control mechanism through the wireless communication mechanism at a client, such as a mobile phone, so as to remotely monitor the product of the present invention, so as to timely handle an emergency.

While the foregoing is directed to the preferred embodiment of the present invention, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the utility model.

Claims (10)

1. An electrolyzed water switch device for detecting water flow based on ionization current is characterized by comprising an ionization plate mechanism, an ionization plate driving mechanism, a first electrode mechanism, a second electrode mechanism, an ionization current detection mechanism, an electrolyzed water mechanism, an electrolysis switch mechanism, a control mechanism and a power supply mechanism;

the ionization plate mechanism, the first electrode mechanism and the second electrode mechanism are all arranged in water to be detected, the ionization plate mechanism is electrically connected with the ionization plate driving mechanism, and the first electrode mechanism and the second electrode mechanism are respectively electrically connected with the ionization current detection mechanism;

the control end of the electrolysis switch mechanism, the ionization plate driving mechanism and the ionization current detection mechanism are electrically connected with the control mechanism respectively, the input end of the electrolysis switch mechanism, the control mechanism, the ionization plate driving mechanism and the ionization current detection mechanism are electrically connected with the power supply mechanism, and the output end of the electrolysis switch mechanism is electrically connected with the water electrolysis mechanism.

2. The electrolyzed water switching apparatus for detecting water flow based on ionization current as claimed in claim 1, wherein the ionization plate drive mechanism comprises a drive module, a first current limit module, a second current limit module, a third current limit module, and a first filtering module;

the driving module is electrically connected with the ionization plate mechanism through the first current limiting module;

the driving module is electrically connected with the power supply mechanism through a second current limiting module and is grounded through the second current limiting module and the first filtering module in sequence;

the driving module is electrically connected with the control mechanism through a third current limiting module.

3. The electrolyzed water switching apparatus based on ionized current detection of water flow of claim 1, wherein the ionized current detection mechanism comprises a current detection module, a fourth current limit module, a fifth current limit module, a sixth current limit module, a seventh current limit module, and a second filtering module;

the first electrode mechanism and the second electrode mechanism are respectively and electrically connected with the current detection module through the fourth current limiting module and the fifth current limiting module;

the current detection module is electrically connected with the power supply mechanism through a sixth current limiting module and is grounded through the sixth current limiting module and the second filtering module in sequence;

the current detection module is electrically connected with the control mechanism through a seventh current limiting module.

4. The electrolyzed water switching apparatus for detecting water flow based on ionization current as defined in claim 1, wherein the electrolysis switching mechanism comprises a first switching module, an eighth current limiting module, a ninth current limiting module, and a third filtering module;

the output end of the first switch module is the output end of the electrolysis switch mechanism;

one end of the eighth current limiting module is the input end of the electrolytic switching mechanism and is grounded through the third filtering module, and the other end of the eighth current limiting module is connected with the input end of the first switching module;

one end of the ninth current limiting module is a control end of the electrolysis switching mechanism, and the other end of the ninth current limiting module is connected with the control end of the first switching module.

5. The electrolyzed water switching apparatus for detecting water flow based on ionization current as claimed in claim 1, wherein the power supply mechanism comprises a first power supply module, a first voltage conversion module, a change-over switch module, a second power supply module, a second voltage conversion module, a charge switch module, and a low-power detection module;

the input end of the first voltage conversion module is electrically connected with the first power supply module, the output end of the first voltage conversion module is electrically connected with the control end and the output end of the change-over switch module and the input end of the charging switch module, the input end of the change-over switch module and one end of the low-power detection module are both electrically connected with the second power supply module, the control end of the charging switch module and the other end of the low-current detection module are respectively electrically connected with the control mechanism, the output end of the charging switch module is electrically connected with the charging end of the second power supply module, the input end of the second voltage conversion module is electrically connected with the output end of the change-over switch module, the input end of the electrolysis switch mechanism and the ionization plate driving mechanism, the output end of the second voltage conversion module is electrically connected with the ionization current detection mechanism and the control mechanism;

the first voltage conversion module is a direct current-to-alternating current power adapter.

6. The electrolyzed water switching apparatus for detecting water flow based on ionization current as claimed in claim 5, wherein the change-over switch module comprises a first switch unit, a first current limiting unit, a second current limiting unit, a first filtering unit, and a second filtering unit;

one end of the first current limiting unit is a control end of the change-over switch module and is grounded through the first filtering unit, and the other end of the first current limiting unit is electrically connected with the control end of the first switch unit;

one end of the second current limiting unit is the input end of the change-over switch module and is grounded through the second filtering unit, and the other end of the second current limiting unit is electrically connected with the input end of the first switch unit;

the output end of the first switch unit is the output end of the change-over switch module.

7. The electrolyzed water switching apparatus for detecting water flow based on ionization current as claimed in claim 5, wherein the charge switch module comprises a second switch unit, a third current limiting unit, a fourth current limiting unit, a third filtering unit, and a fourth filtering unit;

one end of the third current limiting unit is a control end of the charging switch module, and the other end of the third current limiting unit is electrically connected with the control end of the second switch unit;

one end of the fourth current limiting unit is the input end of the charging switch module and is grounded through the third filtering unit, and the other end of the fourth current limiting unit is electrically connected with the input end of the second switch unit;

the output end of the second switch unit is the output end of the charging switch module and is grounded through the fourth filtering unit.

8. The electrolyzed water switching apparatus for detecting water flow based on ionization current as claimed in claim 5, wherein the second voltage conversion module comprises a voltage conversion unit, a fifth filter unit, and a sixth filter unit;

the input end of the voltage conversion unit is the input end of the second voltage conversion module and is grounded through the fifth filtering unit;

the output end of the voltage conversion unit is the output end of the second voltage conversion module and is grounded through the sixth filtering unit.

9. The electrolyzed water switching device for detecting water flow based on ionized current as claimed in any of claims 1 to 8, further comprising a warning mechanism, wherein the warning mechanism comprises an indicator light module, a speaker module, a second switch module, a tenth current limiting module, an eleventh current limiting module and a fourth filtering module;

the input end of the second switch module is electrically connected with the power supply mechanism through the tenth current-limiting module and is sequentially grounded through the tenth current-limiting module and the fourth filtering module, the control end of the second switch module is electrically connected with the control mechanism through the eleventh current-limiting module, the output end of the second switch module is grounded through the indicator lamp module, and the loudspeaker module is connected with the indicator lamp module in parallel.

10. The electrolyzed water switching device for detecting water flow based on ionized current as claimed in any of claims 1 to 8, further comprising a wireless communication mechanism, wherein the wireless communication mechanism is electrically connected with the power supply mechanism and the control mechanism.

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