CN218642537U - Waterway disinfection system of oral cavity comprehensive treatment table and oral cavity comprehensive treatment table - Google Patents

Abstract

The utility model relates to a waterway disinfection system of an oral comprehensive treatment table, which comprises a first pipeline, a second pipeline and a disinfection module; the first pipeline is communicated to the disinfection module and is provided with a flow sensor; the first end of the second pipeline is communicated to the first pipeline, the second end of the second pipeline is communicated to the first pipeline, and the flow sensor is arranged between the first end and the second end of the second pipeline, or the first end of the second pipeline is communicated to the first pipeline, and the second end of the second pipeline is communicated to the disinfection module; the first pipeline is internally provided with a jet orifice communicated with the first pipeline, and the jet orifice enables water to preferentially flow to the first pipeline when passing through the joint of the first pipeline and the second pipeline; the disinfection module is used for converting the introduced water body into disinfection water and is provided with a water outlet end.

Description

Waterway disinfection system of oral cavity comprehensive treatment table and oral cavity comprehensive treatment table

Technical Field

The utility model relates to an oral cavity comprehensive treatment platform water route disinfection system and oral cavity comprehensive treatment platform.

Background

The water supply system of the oral cavity comprehensive treatment table is easy to cause bacteria in the tube cavity to gather and breed due to the reasons of small diameter of a water path pipeline, slow liquid flowing, intermittent stagnation, pollution caused by instantaneous negative pressure reverse suction and the like. The discharged water has potential infection risk to patients and medical staff, and becomes a difficult point for controlling infection in the oral diagnosis and treatment process.

The current flow sensors on the market have the defect of flow range adaptability, most flow sensors cannot be started under the condition of low flow (lower than the sensing range), and the low flow sensors can monitor low flow, but the aperture of the low flow sensors is too small, so that the water flow beyond the sensing range cannot pass through, and the water flow is limited. At present, a flow sensor which can be compatible with large and small flow ranges cannot be found in the market, namely, the pipeline disinfection system cannot be compatible with starting under multi-range flow, so that the application is limited.

SUMMERY OF THE UTILITY MODEL

Based on the problem mentioned above, the utility model provides an oral cavity is synthesized treatment table water route disinfection system and oral cavity and is synthesized treatment table.

The waterway disinfection system of the oral cavity comprehensive treatment table comprises a first pipeline, a second pipeline and a disinfection module;

the first pipeline is communicated to the disinfection module and is provided with a flow sensor;

the first end of the second pipeline is communicated to the first pipeline, the second end of the second pipeline is communicated to the first pipeline, and the flow sensor is arranged between the first end and the second end of the second pipeline, or the first end of the second pipeline is communicated to the first pipeline, and the second end of the second pipeline is communicated to the disinfection module;

the first pipeline is internally provided with a jet orifice communicated with the first pipeline, and the jet orifice enables water to preferentially flow to the first pipeline when passing through the communication part of the first pipeline and the second pipeline;

the disinfection module is used for converting the introduced water body into disinfection water and is provided with a water outlet end.

In one embodiment, the jet orifice is disposed downstream of a connection point of the second conduit with the first conduit.

The waterway disinfection system of the oral cavity comprehensive treatment table comprises a water inlet end pipeline, a first pipeline, a second pipeline and a disinfection module;

a first end of the first pipeline is communicated to the water inlet end pipeline, and a second end of the first pipeline is communicated to the disinfection module;

the first pipeline is provided with a flow sensor;

a first end of the second pipeline is communicated with the water inlet end pipeline, a second end of the second pipeline is communicated to the disinfection module, or a second end of the second pipeline is communicated to the first pipeline;

the water inlet end pipeline or the first pipeline is internally provided with a jet port, and the jet port enables water in the water inlet end pipeline to preferentially flow to the first pipeline;

the disinfection module is used for converting the introduced water body into disinfection water and is provided with a water outlet end.

In one embodiment, the jet opening is arranged downstream of the connection point of the second pipeline and the water inlet end pipeline.

In one embodiment, a jet structure body is arranged in the water inlet end pipeline, the bottom of the jet structure body extends towards the direction close to the flow sensor to form the jet opening, and the width of the jet structure body is gradually reduced from the bottom to the jet opening.

In one embodiment, the second end of the second pipeline is communicated to the first pipeline, and the water outlet of the flow sensor is arranged at the downstream of the connection point of the first pipeline and the second pipeline.

In one embodiment, the flow sensor has a value in the range of 5-500ml/min.

In one embodiment, the disinfection module comprises an electrolysis unit comprising an anode, an ion exchange membrane and a cathode arranged in sequence.

In one embodiment, the material of the anode is one of conductive silicon, conductive diamond, titanium, platinum, lead oxide, tantalum oxide.

An oral cavity comprehensive treatment table comprises the waterway disinfection system of the oral cavity comprehensive treatment table.

The beneficial effects of the utility model are that:

the water body flows in from the water supply source and can be divided into a first pipeline and a second pipeline, when the water body flows through the first pipeline, the flow sensor measures water flow, and the disinfection module is started. Because no flow sensor or other valve components are arranged in the second pipeline, the water body easily flows to the second pipeline to enable the first pipeline to have low flow or no flow, and the disinfection module is difficult to start. Therefore, the utility model discloses well water inlet end pipeline or first pipeline pass through the jet orifice and make the water preferentially circulate to first pipeline. When the flow of the water body exceeds the carrying capacity of the first pipeline, the water flow is shunted into the second pipeline, so that the waterway disinfection system can be started in a compatible multi-range flow manner. And a switch component is not required to be arranged in the second pipeline, so that the integral structure is simpler and the production and maintenance cost is lower. The water body is introduced into the disinfection module to be converted into the disinfection water with the sterilization and disinfection effect, and the pipeline or the oral cavity of a patient can be sterilized and disinfected.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without inventive exercise.

Fig. 1 is a schematic view of a waterway disinfection system of an oral complex treatment table according to an embodiment.

Fig. 2 is a schematic view of a waterway disinfection system of an oral complex treatment table according to another embodiment.

Fig. 3 is a schematic view of a waterway disinfection system of an oral cavity comprehensive treatment table according to still another embodiment.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1, a waterway disinfection system for an oral cavity complex treatment table according to a preferred embodiment of the present invention includes a first pipeline 100, a second pipeline 200, and a disinfection module 900.

The first line 100 is connected to the sterilization module 900, and the first line 100 is provided with a flow sensor 400.

A first end of the second pipeline 200 is communicated to the first pipeline 100, a second end of the second pipeline 200 is communicated to the first pipeline 100, and the flow sensor 400 is disposed between the first end and the second end of the second pipeline 200, or the first end of the second pipeline 200 is communicated to the first pipeline 100, and the second end of the second pipeline 200 is communicated to the sterilization module 900.

The first pipeline 100 is provided with a jet orifice 301 communicated with the first pipeline, and the jet orifice 301 enables water to preferentially circulate to the first pipeline 100 when the first pipeline 100 is communicated with the second pipeline 200.

The disinfection module 900 is used for converting the introduced water into disinfection water, and the disinfection module 900 is provided with a water outlet end.

The beneficial effect of this embodiment does:

the water body flows into the first pipeline 100 from the water supply source, the flow sensor 400 is disposed in the first pipeline 100, the flow sensor 400 measures the water flow when the water body flows through, the sterilizing module 900 is started, and the water body can be communicated to the second pipeline 200 through the communication part of the first pipeline 100 and the second pipeline 200. Because the second pipeline 200 is not provided with the flow sensor 400 or other valve components, the water body flowing through the communication part (or the connection part) of the first pipeline 100 and the second pipeline 200 can easily flow to the second pipeline 200, so that the first pipeline 100 has low flow or no flow, and the disinfection module 900 is difficult to start. Therefore, in this embodiment, the first pipeline 100 has a jet orifice 301 communicated therewith, so that when the water body passes through the communication (or connection) between the first pipeline 100 and the second pipeline 200, the water body preferentially circulates into the first pipeline 100. When the flow of the water body exceeds the bearing capacity of the first pipeline 100, the water flow is divided into the second pipeline 200, so that the waterway disinfection system can be started in a compatible multi-range flow manner. The water body is introduced into the disinfection module 900 and is converted into the disinfection water with the sterilization and disinfection effects, and the pipeline or the oral cavity of a patient can be sterilized and disinfected.

In order to realize the preferential circulation of the water body into the first pipeline 100 when the water body passes through the communication part (or the connection part) of the first pipeline 100 and the second pipeline 200, specifically, in one embodiment, as shown in fig. 1, the jet orifice 301 is disposed downstream of the connection point of the second pipeline 200 and the first pipeline 100. That is, the jet orifice 301 exceeds the position of the connection between the first pipeline 100 and the second pipeline 200, so that the water flow is preferentially sent to the first pipeline 100 and flows into the flow sensor 400.

The utility model provides a waterway disinfection system of an oral cavity comprehensive treatment table, as shown in fig. 2 and 3, comprising a water inlet pipeline 109, a first pipeline 100, a second pipeline 200 and a disinfection module 900.

A first end of the first pipeline 100 is connected to the water inlet pipeline 109, a second end of the first pipeline 100 is connected to the disinfection module 900, and the first pipeline 100 is provided with a flow sensor 400.

A first end of the second line 200 is connected to the inlet line 109, a second end of the second line 200 is connected to the sterilization module 900, or a second end of the second line 200 is connected to the first line 100.

The water inlet end pipeline 109 or the first pipeline 100 is provided with a jet orifice 301, and the jet orifice 301 enables the water body in the water inlet end pipeline 109 to preferentially circulate to the first pipeline 100.

The disinfection module 900 is used for converting the introduced water into disinfection water, and the disinfection module 900 is provided with a water outlet end.

The beneficial effect of this embodiment does:

the water flows into the water inlet end pipeline 109 from the water supply source and can be divided into a first pipeline 100 and a second pipeline 200, the first pipeline 100 is provided with a flow sensor 400, when the water flows through, the flow sensor 400 measures the water flow, and the disinfection module 900 is started. Because the second pipeline 200 is not provided with the flow sensor 400 or other valve components, the water body easily flows to the second pipeline 200, so that the first pipeline 100 has low flow or no flow, and the disinfection module 900 is difficult to start. Therefore, in this embodiment, the inlet end pipeline 109 has a jet orifice 301 therein, which is communicated with the inlet end pipeline 109, so that the water in the inlet end pipeline 109 preferentially flows into the first pipeline 100. When the flow of the water body exceeds the bearing capacity of the first pipeline 100, the water flow is divided into the second pipeline 200, so that the waterway disinfection system can be started in a compatible multi-range flow manner. The water body is introduced into the disinfection module 900 and is converted into the disinfection water with the sterilization and disinfection effect, and the pipeline or the oral cavity of the patient can be sterilized and disinfected.

In the above embodiment, the first pipeline 100 is used to pass a small flow, the flow sensor 400 on the first pipeline 100 is used to monitor the water flow path in the first pipeline 100, and the value range of the flow sensor 400 can be adjusted according to the flow demand of the oral cavity comprehensive treatment table in actual production, so that the flow sensor 400 can be started by sensing in the lowest flow application scene of the oral cavity comprehensive treatment table. When the water flow path exceeds the detection range of the flow sensor 400, the water body is shunted to the first pipeline 100 and the second pipeline 200, the second pipeline 200 is used for bearing a large flow water body, so that the starting of the waterway disinfection system compatible with multiple flow ranges is realized, and a switch component is not required to be arranged in the second pipeline 200, so that the whole structure is simpler and easier, and the production and maintenance costs are lower.

In one embodiment, the flow sensor 400 has a value in the range of 5-500ml/min.

In one embodiment, the flow sensor 400 has a value in the range of 20-150ml/min.

In one embodiment, the flow sensor 400 has a value in the range of 50-100ml/min.

To achieve preferential flow of water from the inlet end pipe 109 to the first pipe 100, for example, when the connection point of the first pipe 100 and the inlet end pipe 109 is located downstream of the connection point of the second connection pipe and the inlet end pipe 109, as shown in fig. 2, in one embodiment, the inlet end pipe 109 has a jet orifice 301 therein, and the jet orifice 301 is located downstream of the connection point of the second pipe 200 and the inlet end pipe 109, that is, the jet orifice 301 exceeds the position of the connection (or connection) between the first pipe 100 and the second pipe 200, so that the water flow is preferentially sent to the first pipe 100 and flows into the flow sensor 400. For example, as shown in fig. 3, when the connection point of the first pipe 100 and the inlet end pipe 109 is disposed upstream of the connection point of the second connection pipe and the inlet end pipe 109, or when the connection point of the first pipe 100 and the inlet end pipe 109 meets/is the same as the connection point of the second connection pipe and the inlet end pipe 109, in another embodiment, the jet port 301 is disposed in the first pipe 100 and is communicated to the inlet end pipe 109, so that the water body is preferentially fed into the first pipe 100 and the inflow sensor 400.

More specifically, for example, as shown in fig. 1 to 3, the water inlet end pipeline 109 or the first pipeline 100 has a fluidic structure 300 therein, the bottom of the fluidic structure 300 extends to a direction close to the flow sensor 400 to form a fluidic port 301, the width of the fluidic structure 300 gradually decreases from the bottom to the fluidic port 301, and as the width gradually decreases, the pressure rises, and the water flow speed rises at the fluidic port 301 to form a jet flow which is sent into the first pipeline 100.

As shown in fig. 3, the second pipeline 200 may be directly connected to the disinfection module 900, so that the water in the second pipeline 200 is introduced into the disinfection module 900, or as shown in fig. 1 and 2, the second pipeline 200 is connected to the first pipeline 100 (downstream of the flow sensor 400), and merges with the water in the first pipeline 100 and is introduced into the disinfection module 900.

For example, the second pipeline 200 is connected to the first pipeline 100, in order to avoid that the large flow of water in the second pipeline 200 blocks the water in the first pipeline 100, so that the water in the flow sensor 400 is difficult to flow out, in one embodiment, as shown in fig. 1 and fig. 2, the water outlet 401 of the flow sensor 400 is disposed downstream of the connection point of the first pipeline 100 and the second pipeline 200, and the water outlet 401 of the flow sensor 400 is communicated with the inside of the first pipeline 100, more specifically, the water outlet end of the flow sensor 400 extends to form a drainage structure 402, the drainage structure 402 extends downstream of the first pipeline 100 and forms the water outlet 401, and the position of the water outlet 401 is disposed downstream of the connection point of the first pipeline 100 and the second pipeline 200, so that the water flowing out from the flow sensor 400 is not blocked by the large flow of water in the second pipeline 200, thereby ensuring the operation of the flow sensor 400.

In one embodiment, the sterilization module 900 includes an electrolysis unit including an anode, an ion exchange membrane, and a cathode arranged in sequence. For example, water is electrolyzed at a low pressure to generate oxidizing radicals such as ozone, oxygen atoms, hydroxyl radicals, and the like, thereby achieving oxidative sterilization.

In one embodiment, the material of the anode is one of conductive silicon, conductive diamond, titanium, platinum, lead oxide, tantalum oxide. For example, the anode is made of conductive diamond, and low-pressure electrolyzed water of the anode can generate ozone with high oxidation-reduction potential, hydroxyl free radicals and the like, so that the reliability of the sterilization effect is ensured.

An oral cavity comprehensive treatment table comprises the waterway disinfection system of the oral cavity comprehensive treatment table. The water generated by the disinfection system is used for disinfecting a water path of a dental bed, and can also be used in dental surgery to disinfect the oral cavity of a patient.

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 represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. The waterway disinfection system of the oral cavity comprehensive treatment table is characterized by comprising a first pipeline, a second pipeline and a disinfection module;

the first pipeline is communicated to the disinfection module and is provided with a flow sensor;

the first end of the second pipeline is communicated to the first pipeline, the second end of the second pipeline is communicated to the first pipeline, and the flow sensor is arranged between the first end and the second end of the second pipeline, or the first end of the second pipeline is communicated to the first pipeline, and the second end of the second pipeline is communicated to the disinfection module;

the first pipeline is internally provided with a jet orifice communicated with the first pipeline, and the jet orifice ensures that water preferentially flows to the first pipeline when passing through the communication part of the first pipeline and the second pipeline;

the disinfection module is used for converting the introduced water body into disinfection water and is provided with a water outlet end.

2. The oral complex treatment table waterway disinfection system of claim 1, wherein the jet orifice is disposed downstream of a connection point of the second pipeline and the first pipeline.

3. The waterway disinfection system of the oral cavity comprehensive treatment table is characterized by comprising a water inlet end pipeline, a first pipeline, a second pipeline and a disinfection module;

the first end of the first pipeline is communicated to the water inlet end pipeline, and the second end of the first pipeline is communicated to the disinfection module;

the first pipeline is provided with a flow sensor;

a first end of the second pipeline is communicated with the water inlet end pipeline, a second end of the second pipeline is communicated to the disinfection module, or a second end of the second pipeline is communicated to the first pipeline;

the water inlet end pipeline or the first pipeline is internally provided with a jet port, and the jet port enables water in the water inlet end pipeline to preferentially flow to the first pipeline;

the disinfection module is used for converting the introduced water body into disinfection water and is provided with a water outlet end.

4. The waterway disinfection system of the oral complex treatment table of claim 3, wherein the jet port is disposed downstream of a connection point of the second pipeline and the water inlet end pipeline.

5. The waterway disinfection system of the oral complex treatment table of claim 1 or 3, wherein the disinfection module comprises an electrolysis unit, and the electrolysis unit comprises an anode, an ion exchange membrane and a cathode which are arranged in sequence.

6. The waterway disinfection system of an oral complex treatment table of claim 5, wherein the anode is made of one of conductive silicon, conductive diamond, titanium, platinum, lead oxide and tantalum oxide.

7. The waterway disinfection system of an oral cavity complex treatment table according to any one of claims 1 to 4, wherein a jet structure body is arranged in the first pipeline, the bottom of the jet structure body extends to a direction close to the flow sensor to form the jet opening, and the width of the jet structure body is gradually reduced from the bottom to the jet opening.

8. The waterway disinfection system of an oral complex treatment table of any one of claims 1-4, wherein a second end of the second pipeline is communicated to the first pipeline, and a water outlet of the flow sensor is disposed downstream of a connection point of the first pipeline and the second pipeline.

9. The waterway disinfection system of the oral cavity complex treatment table according to any one of claims 1 to 4, wherein the flow sensor has a value ranging from 5 to 500ml/min.

10. An oral complex treatment table comprising the waterway disinfection system of any one of claims 1-9.

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