CN110820867A - Self-cleaning method of reciprocating flushing and draining mechanism and mechanism - Google Patents

Abstract

The invention relates to a self-cleaning method of a reciprocating flushing and draining mechanism and the mechanism, wherein the self-cleaning method of the reciprocating flushing and draining mechanism comprises the following steps: s1: controlling the water inlet assembly to enable clean water to flow into the pipe body through the water inlet assembly and the water inlet branch pipe in sequence so as to flush the pipe body; s2: controlling the drainage assembly to enable sewage generated after flushing to be discharged after passing through the pipe body, the drainage branch pipe and the drainage assembly in sequence; s3: and controlling the water inlet assembly to enable the clean water to wash the pipe body again to complete a self-cleaning process. The self-cleaning method of the reciprocating flushing and draining mechanism is simple to operate, and can well realize the self-cleaning effect of the internal shared pipeline, so that the quality of inlet water can be effectively ensured.

Description

Self-cleaning method of reciprocating flushing and draining mechanism and mechanism

Technical Field

The invention relates to the field of household appliances, in particular to a self-cleaning method of a reciprocating type flushing and draining mechanism and the mechanism.

Background

Reciprocating type towards drainage mechanism's one section pipeline of water route and drainage water route meeting sharing for the inside pollution that receives the drainage of sharing pipeline, thereby lead to into water quality of water to receive the influence. The traditional reciprocating flushing and draining mechanism cannot effectively self-clean the shared pipeline, so that the water inlet quality cannot be well guaranteed.

Disclosure of Invention

Therefore, it is necessary to provide a self-cleaning method for a reciprocating flushing and draining mechanism and a reciprocating flushing and draining mechanism, aiming at the problem that the reciprocating flushing and draining mechanism cannot realize self-cleaning of a common pipeline.

A self-cleaning method of a reciprocating type flushing and draining mechanism comprises the following steps:

s1: controlling the water inlet assembly to enable clean water to flow into the pipe body through the water inlet assembly and the water inlet branch pipe in sequence so as to flush the pipe body;

s2: controlling the drainage assembly to enable sewage generated after flushing to be discharged after passing through the pipe body, the drainage branch pipe and the drainage assembly in sequence;

s3: and controlling the water inlet assembly to enable the clean water to wash the pipe body again to complete a self-cleaning process.

According to the self-cleaning method of the reciprocating flushing and draining mechanism, clear water is introduced into the pipe body from the water inlet branch pipe by controlling the water inlet assembly so as to flush and clean the inner pipe wall of the pipe body; sewage generated after washing enters the drainage assembly through the pipe body and the drainage branch pipe and is discharged; and finally, injecting clear water into the pipe body by controlling the water inlet assembly so as to wash the pipe body again. Therefore, the pipe body can be effectively cleaned after sewage is drained every time, so that the inside of the pipe body is clean, and the water inlet quality is prevented from being polluted by drainage. The self-cleaning method of the reciprocating flushing and draining mechanism is simple to operate, and can well realize the self-cleaning effect of the shared pipeline, so that the quality of inlet water can be effectively ensured.

In one embodiment, the step S1 further includes: controlling the drainage assembly to enable part of clear water in the water inlet branch pipe to sequentially flow through the drainage branch pipe and the drainage assembly and then be discharged; and/or the presence of a gas in the gas,

the step S3 further includes: and controlling the drainage assembly to enable part of the clear water in the water inlet branch pipe to sequentially flow through the drainage branch pipe and the drainage assembly and then be discharged.

In one embodiment, before the step S3, the method further includes the following steps:

s21: the loop repeats step S1 and step S2N times, where N is an integer greater than or equal to 1.

In one embodiment, before the step S1, the method further includes the following steps:

s0: the method includes detecting a degree of contamination of an inner wall of the pipe body, and determining an N value based on the detected degree of contamination of the inner wall of the pipe body.

A reciprocating type flushing and draining mechanism comprises a water inlet assembly, a draining assembly, a connecting pipe and a container, wherein the connecting pipe comprises a pipe body, a water inlet branch pipe and a draining branch pipe, and a water passing port communicated with the container is formed in the pipe body; the water inlet assembly, the water inlet branch pipe and the pipe body are communicated in sequence so that water can be injected into the container; the drainage assembly, the drainage branch pipe and the pipe body are communicated in sequence so that water is sucked out of the container.

The reciprocating flushing and draining mechanism is used for communicating the water inlet assembly with the water inlet branch pipe, and communicating the draining assembly with the draining branch pipe, wherein the water inlet assembly, the water inlet branch pipe and the pipe body are sequentially connected to form a water inlet channel, and the pipe body, the draining branch pipe and the draining assembly are sequentially connected to form a draining channel. So for inhalant canal and drainage channel are in the mutual independence of part except that managing the body, thereby can effectively avoid inhalant subassembly and water inlet branch pipe to receive the pollution of drainage, and then reduced the influence of drainage to the quality of water of intaking to a great extent.

When the pipe body needs to be cleaned, firstly, the water inlet assembly is controlled so that clean water in the water inlet assembly enters the pipe body through the water inlet branch pipe to wash and clean the inner pipe wall of the pipe body, sewage generated after cleaning is injected into the container through the water inlet, then the water drainage assembly is controlled so that the sewage in the container is sucked into the pipe body through the water inlet, and then the sewage is discharged through the water drainage branch pipe and the water drainage assembly, and finally the water inlet assembly is controlled to wash and clean the inner pipe wall of the pipe body again, so that the inner pipe wall of the pipe body is effectively cleaned, and the quality of inlet water is further guaranteed.

In one embodiment, the water inlet branch pipe and the water outlet branch pipe extend coaxially and are communicated, one end of the pipe body is communicated with both the water inlet branch pipe and the water outlet branch pipe, and the water passing opening is formed at the other end of the pipe body.

In one embodiment, the reciprocating flushing and draining mechanism further comprises a turbidity sensor arranged in the pipe body, and the turbidity sensor is used for detecting the turbidity of the inner pipe wall of the pipe body.

In one embodiment, the reciprocating flushing and draining mechanism further comprises a filter member disposed within the tube body.

In one embodiment, the water inlet assembly comprises a water inlet valve and a water inlet pipe, and the water inlet valve, the water inlet pipe and the water inlet branch pipe are sequentially communicated; and/or the drainage component comprises a drainage pipe, a drainage valve and a drainage pump, and the drainage branch pipe, the drainage valve and the drainage pump are communicated in sequence.

In one embodiment, a water inlet flow meter is arranged between the water inlet valve and the water inlet pipe; and/or a drainage flowmeter is arranged between the drainage pipe and the drainage valve.

Drawings

FIG. 1 is a schematic flow chart illustrating a self-cleaning method for a reciprocating flushing and draining mechanism according to an embodiment of the present invention;

FIG. 2 is a schematic flow chart illustrating a self-cleaning method for a reciprocating flushing and draining mechanism according to another embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a reciprocating flushing and draining mechanism according to an embodiment of the present invention;

FIG. 4 is an exploded view of the reciprocating flushing and draining mechanism of FIG. 3;

fig. 5 is a schematic structural view of the connection pipe in fig. 4.

10. The water inlet assembly comprises a water inlet assembly 11, a water inlet valve 12, a water inlet pipe 13, a water inlet flow meter 20, a drainage assembly 21, a drainage pipe 22, a drainage valve 23, a drainage pump 24, a drainage flow meter 30, a connecting pipe 31, a pipe body 310, a water passing port 311, a first folding pipe 312, a second folding pipe 313, a connecting rib 32, a water inlet branch pipe 33, a drainage branch pipe 40 and a filtering piece.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. In contrast, when an element is referred to as being "directly on" another element, there are no intervening elements present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Example 1

Referring to fig. 1, a self-cleaning method for a reciprocating flushing and draining mechanism includes the following steps:

s1: controlling the water inlet assembly to enable clean water to flow into the pipe body through the water inlet assembly and the water inlet branch pipe in sequence so as to flush the pipe body;

s2: controlling the drainage assembly to enable sewage generated after flushing to be discharged after passing through the pipe body, the drainage branch pipe and the drainage assembly in sequence;

s3: and controlling the water inlet assembly to enable the clean water to wash the pipe body again to complete a self-cleaning process.

According to the self-cleaning method of the reciprocating flushing and draining mechanism, clear water is introduced into the pipe body from the water inlet branch pipe by controlling the water inlet assembly so as to flush and clean the inner pipe wall of the pipe body; sewage generated after washing enters the drainage assembly through the pipe body and the drainage branch pipe and is discharged; and finally, injecting clear water into the pipe body by controlling the water inlet assembly so as to wash the pipe body again. Therefore, the pipe body can be effectively cleaned after sewage is drained every time, so that the inside of the pipe body is clean, and the water inlet quality is prevented from being polluted by drainage. The self-cleaning method of the reciprocating flushing and draining mechanism is simple to operate, and can well realize the self-cleaning effect of the shared pipeline, so that the quality of inlet water can be effectively ensured.

Example 2

A self-cleaning method of a reciprocating type flushing and draining mechanism comprises the following steps:

s1: controlling the water inlet assembly to enable clean water to flow into the pipe body through the water inlet assembly and the water inlet branch pipe in sequence so as to flush the pipe body; controlling the drainage assembly to enable part of clear water in the water inlet branch pipe to sequentially flow through the drainage branch pipe and the drainage assembly and then be discharged;

s2: controlling the drainage assembly to enable sewage generated after flushing to be discharged after passing through the pipe body, the drainage branch pipe and the drainage assembly in sequence;

s3: and controlling the water inlet assembly to enable the clean water to wash the pipe body again to complete a self-cleaning process.

In step S1 of the self-cleaning method for the reciprocating flushing and draining mechanism, the water inlet assembly and the water draining assembly are controlled so that clean water can flow into the pipe body from the water inlet assembly and the water inlet branch pipe to flush the pipe body, and meanwhile, part of the clean water in the water inlet branch pipe can flow into the water draining branch pipe and the water draining assembly under the suction force of the water draining assembly so as to flush the water draining branch pipe and the water draining assembly. Therefore, the pipe body is effectively cleaned, the drainage branch pipe and the drainage assembly can be cleaned together, and the whole reciprocating type flushing and drainage mechanism can be effectively cleaned. In addition, the water inlet and the water discharge work simultaneously, and the flushing efficiency can be effectively improved.

Example 3

A self-cleaning method of a reciprocating type flushing and draining mechanism comprises the following steps:

s1: controlling the water inlet assembly to enable clean water to flow into the pipe body through the water inlet assembly and the water inlet branch pipe in sequence so as to flush the pipe body;

s2: controlling the drainage assembly to enable sewage generated after flushing to be discharged after passing through the pipe body, the drainage branch pipe and the drainage assembly in sequence;

s3: controlling the water inlet assembly to enable the clean water to wash the pipe body again; and controlling the drainage assembly to enable part of clear water in the water inlet branch pipe to sequentially flow through the drainage branch pipe and the drainage assembly and then be discharged, so that a one-time self-cleaning process is completed.

The self-cleaning method of the reciprocating flushing and draining mechanism firstly washes and cleans the pipe body through the steps S1 and S2, and then enables the clear water to wash the pipe body and simultaneously enables partial clear water in the water inlet branch pipe to enter the water outlet branch pipe and the water outlet assembly under the suction force of the water outlet assembly through controlling the water inlet assembly and the water outlet assembly in the step S3 so as to wash the water outlet branch pipe and the water outlet assembly, thereby effectively cleaning the whole reciprocating flushing and draining mechanism.

Example 4

Referring to fig. 2, a self-cleaning method for a reciprocating flushing and draining mechanism includes the following steps:

s1: controlling the water inlet assembly to enable clean water to flow into the pipe body through the water inlet assembly and the water inlet branch pipe in sequence so as to flush the pipe body;

s2: controlling the drainage assembly to enable sewage generated after flushing to be discharged after passing through the pipe body, the drainage branch pipe and the drainage assembly in sequence;

s21: repeating the steps S1 and S2 circularly for N times, wherein N is an integer greater than or equal to 1;

s3: and controlling the water inlet assembly to enable the clean water to wash the pipe body again to complete a self-cleaning process.

On the basis of the above embodiment, by adding step S21 before step S3, that is, performing repeated water feeding and draining operations, the inner wall of the pipe body is effectively cleaned, so as to ensure that the inside of the pipe body can be cleaned. Wherein repeated number of times N can set up according to actual demand, for example, can set up according to the pollution degree of pipe wall in this body of pipe, and when the pollution degree of pipe wall was less in this body of pipe, N value set for relatively less, so in order to guarantee that the pipe body can obtain effective clear while, can not waste too much water resource. When the pollution degree of the inner pipe wall of the pipe body is large, the N value is set to be relatively large so as to ensure that the inner pipe wall of the pipe body can be cleaned.

Optionally, before the step S1, the following steps are further included:

s0: the method includes detecting a degree of contamination of an inner wall of the pipe body, and determining an N value based on the detected degree of contamination of the inner wall of the pipe body.

Through the result of dirty degree sensor feedback for the user can be accurate the settlement N value, so that reciprocating type dashes drainage mechanism's self-cleaning effect is optimal.

Example 5

Referring to fig. 3 to 5, a reciprocating flushing and draining mechanism includes a water inlet assembly 10, a water draining assembly 20, a connecting pipe 30 and a container (not shown), wherein the connecting pipe 30 includes a pipe body 31, a water inlet branch pipe 32 and a water draining branch pipe 33, and the pipe body 31 is provided with a water passing opening 310 communicated with the container; the water inlet assembly 10, the water inlet branch pipe 32 and the pipe body 31 are communicated in sequence so that water can be injected into the container; the drain assembly 20, the drain branch pipe 33 and the pipe body 31 are sequentially communicated to suck water out of the container.

The reciprocating flushing and draining mechanism is used for communicating the water inlet component 10 with the water inlet branch pipe 32 and communicating the water draining component 20 with the water draining branch pipe 33, wherein the water inlet component 10, the water inlet branch pipe 32 and the pipe body 31 are sequentially connected to form a water inlet channel, and the pipe body 31, the water draining branch pipe 33 and the water draining component 20 are sequentially connected to form a water draining channel. So for inhalant canal and drainage channel are in the mutual independence of part except that tub body 31, thereby can effectively avoid inhalant subassembly 10 and intake branch 32 to receive the pollution of drainage, and then reduced the influence of drainage to the quality of water of intaking to a great extent.

When the pipe body 31 needs to be cleaned, the water inlet assembly 10 is controlled firstly, so that clean water in the water inlet assembly 10 enters the pipe body 31 through the water inlet branch pipe 32 to wash and clean the inner pipe wall of the pipe body 31, sewage generated after cleaning is injected into the container through the water outlet 310, then the water discharge assembly 20 is controlled to suck the sewage in the container into the pipe body 31 through the water outlet 310, then the sewage is discharged through the water discharge branch pipe 33 and the water discharge assembly 20, and finally the water inlet assembly 10 is controlled to wash and clean the inner pipe wall of the pipe body 31 again, so that the inner pipe wall of the pipe body 31 is effectively cleaned, and the quality of inlet water is further guaranteed.

Further, the water inlet branch pipe 32 and the water outlet branch pipe 33 extend coaxially and communicate with each other, one end of the pipe body 31 communicates with both the water inlet branch pipe 32 and the water outlet branch pipe 33, and the other end of the pipe body 31 is formed with a water passing opening 310.

Specifically, the inlet branch pipe 32 and the outlet branch pipe 33 extend coaxially, and the axes of the inlet branch pipe 32 and the outlet branch pipe 33 intersect with the axis of the pipe body 31. Thus, when the water inlet module 10 and the water outlet module 20 operate simultaneously, a part of water in the water inlet branch pipe 32 flows out from the water passing opening 310 of the pipe body 31, and the other part of water can enter the water outlet branch pipe 33 and the water outlet module 20 under the action of inertia and the suction force of the water outlet module 20, so that the water outlet branch pipe 33 and the water outlet module 20 can be flushed, and the whole reciprocating flushing and water draining mechanism can be cleaned.

Further, the extending direction of the inlet branch pipe 32 and the outlet branch pipe 33 is perpendicular to the extending direction of the pipe body 31. The extending direction of the inlet branch pipe 32 and the outlet branch pipe 33 is perpendicular to the extending direction of the pipe body 31. Specifically, the water inlet branch pipe 32, the water outlet branch pipe 33 and the pipe body 31 are connected to form a T-shaped pipe, so that the structure is simple, and the production and the manufacture are convenient.

Optionally, the pipe body 31 includes a first folding pipe 311 and a second folding pipe 312 which are communicated with each other, the first folding pipe 311 is communicated with the water inlet branch pipe 32 and the water outlet branch pipe 33, and a water outlet 310 is formed at an end of the second folding pipe 312 which is far away from the first folding pipe 311. The outer wall surface of the first folding pipe 311 connected with the second folding pipe 312 is provided with a connecting rib 313. By providing the connecting rib 313, the structure of the pipe body 31 can be reinforced.

Further, the reciprocating flushing and draining mechanism further includes a turbidity sensor (not shown) provided in the pipe body 31, and the turbidity sensor is configured to detect a turbidity of the inner wall of the pipe body 31. Through the result fed back by the turbidity sensor, the user can accurately set the reciprocating times of water inlet and outlet, so that the self-cleaning effect of the reciprocating flushing and water outlet mechanism is optimal.

Further, referring to fig. 5, the reciprocating flushing and draining mechanism further includes a filtering member 40 disposed in the pipe body 31. Can filter the impurity in the water route of intaking through setting up and filtering piece 40 to the quality of water of intaking has further been guaranteed. For example, a strainer may be provided at the water passing port 310 of the pipe body 31.

Further, referring to fig. 3 and 4, the water inlet assembly 10 includes a water inlet valve 11 and a water inlet pipe 12, and the water inlet valve 11, the water inlet pipe 12 and the water inlet branch pipe 32 are sequentially communicated; and/or, the drain assembly 20 includes a drain pipe 21, a drain valve 22 and a drain pump 23, and the drain branch pipe 33, the drain pipe 21, the drain valve 22 and the drain pump 23 are sequentially communicated.

Specifically, when the pipe body 31 needs to be flushed, the water inlet valve 11 is opened, the water outlet valve 22 is closed, and water flows through the water inlet valve 11, the water inlet pipe 12 and the water inlet branch pipe 32 and finally flows out of the water outlet 310 of the pipe body 31; when the sewage needs to be discharged, the drain valve 22 and the drain pump 23 are opened, the water inlet valve 11 is closed, and the water is sucked from the water passing port 310 of the pipe body 31, sequentially flows through the drain branch pipe 33, the drain pipe 21, the drain valve 22 and the drain pump 23, and is discharged; when the whole reciprocating flushing and draining mechanism needs to be cleaned, the water inlet valve 11, the water outlet valve 22 and the water draining pump 23 are opened at the same time, a part of water in the water inlet assembly 10 flows into the pipe body 31 from the water inlet branch pipe 32 to flush the pipe body 31, and the other part of water flows into the water draining branch pipe 33 from the water inlet branch pipe 32 under the suction force of the water draining pump 23, and then flows through the water draining pipe 21, the water draining valve 22 and the water draining pump 23 in sequence to be drained, so that the water draining branch pipe 33 and the water draining assembly 20 can be flushed and cleaned.

Further, a water inlet flow meter 13 is arranged between the water inlet valve 11 and the water inlet pipe 12; and/or a drainage flow meter 24 is arranged between the drainage pipe 21 and the drainage valve 22.

The water inflow meter 13 and the water discharge meter 24 are arranged to respectively control the water inflow and the water discharge so as to ensure the flow control precision of the whole reciprocating flushing and water discharging mechanism. Specifically, when the water inlet valve 11 is opened and the water discharge valve 22 is closed, the amount of inlet water can be metered and controlled through the water inlet flow meter 13; when the water inlet valve 11 is closed and the drain valve 22 is opened, the amount of the drained water can be metered and controlled through the drain flow meter 24; when the water inlet valve 11 and the water discharge valve 22 are opened simultaneously, the amount of water to be discharged can be controlled by measuring the difference between the water inlet flow meter 13 and the water discharge flow meter 24.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A self-cleaning method of a reciprocating type flushing and draining mechanism is characterized by comprising the following steps:

s1: controlling the water inlet assembly to enable clean water to flow into the pipe body through the water inlet assembly and the water inlet branch pipe in sequence so as to flush the pipe body;

s2: controlling the drainage assembly to enable sewage generated after flushing to be discharged after passing through the pipe body, the drainage branch pipe and the drainage assembly in sequence;

s3: and controlling the water inlet assembly to enable the clean water to wash the pipe body again to complete a self-cleaning process.

2. The self-cleaning method of a reciprocating flushing and draining mechanism of claim 1, wherein said step S1 further comprises: controlling the drainage assembly to enable part of clear water in the water inlet branch pipe to sequentially flow through the drainage branch pipe and the drainage assembly and then be discharged; and/or the presence of a gas in the gas,

the step S3 further includes: and controlling the drainage assembly to enable part of the clear water in the water inlet branch pipe to sequentially flow through the drainage branch pipe and the drainage assembly and then be discharged.

3. The self-cleaning method of the reciprocating flushing and draining mechanism of claim 1 or 2, further comprising the following steps before the step S3:

s21: the loop repeats step S1 and step S2N times, where N is an integer greater than or equal to 1.

4. The self-cleaning method of a reciprocating flushing and draining mechanism of claim 3, further comprising the following steps before the step S1:

s0: the method includes detecting a degree of contamination of an inner wall of the pipe body, and determining an N value based on the detected degree of contamination of the inner wall of the pipe body.

5. A reciprocating flushing and draining mechanism is characterized by comprising a water inlet assembly, a draining assembly, a connecting pipe and a container, wherein the connecting pipe comprises a pipe body, a water inlet branch pipe and a draining branch pipe, and a water passing port communicated with the container is formed in the pipe body; the water inlet assembly, the water inlet branch pipe and the pipe body are communicated in sequence so that water can be injected into the container; the drainage assembly, the drainage branch pipe and the pipe body are communicated in sequence so that water is sucked out of the container.

6. The reciprocating flushing and draining mechanism of claim 5, wherein said water inlet branch pipe and said water outlet branch pipe extend coaxially and communicate, one end of said pipe body communicates with both said water inlet branch pipe and said water outlet branch pipe, and the other end of said pipe body is formed with said water passing opening.

7. The reciprocating flushing drain mechanism of claim 5 further comprising a turbidity sensor disposed within the tube body for detecting turbidity of the inner tube wall of the tube body.

8. The reciprocating flushing drain mechanism of claim 5 further comprising a filter member disposed within the tube body.

9. The reciprocating flushing and draining mechanism as claimed in any one of claims 5 to 8, wherein said water inlet assembly includes a water inlet valve and a water inlet pipe, said water inlet valve, water inlet pipe and water inlet branch pipe are communicated in sequence; and/or the drainage component comprises a drainage pipe, a drainage valve and a drainage pump, and the drainage branch pipe, the drainage valve and the drainage pump are communicated in sequence.

10. The reciprocating flushing and draining mechanism of claim 9 wherein an inlet flow meter is disposed between said inlet valve and said inlet pipe; and/or a drainage flowmeter is arranged between the drainage pipe and the drainage valve.

Images