CN216603778U - Sterilizing machine - Google Patents
Sterilizing machine Download PDFInfo
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- CN216603778U CN216603778U CN202123040065.3U CN202123040065U CN216603778U CN 216603778 U CN216603778 U CN 216603778U CN 202123040065 U CN202123040065 U CN 202123040065U CN 216603778 U CN216603778 U CN 216603778U
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Abstract
The utility model discloses a sterilizing machine, which comprises an ozone water generating assembly, a telescopic spray head assembly and an induction assembly; the ozone water generating assembly is connected with the telescopic sprayer assembly, the induction assembly is arranged at the telescopic sprayer assembly, and an induction distance is preset in the induction assembly. When the part to be induced is placed below the telescopic spray head assembly to be disinfected, the induction assembly induces signals and respectively transmits the signals to the ozone water generation assembly and the telescopic spray head assembly; ozone water generates the subassembly and receives control ozone water production behind this signal, and, control shower nozzle stretches out after this signal is received to flexible shower nozzle subassembly, because the signal that response subassembly itself received satisfies predetermined response distance, this response distance is eliminated and is treated the induction part and stretch out and draw back the distance that the shower nozzle subassembly probably contacted, consequently the affirmation signal can not cause in this within range to treat the induction part and contact the shower nozzle, then the shower nozzle can stretch out this moment, avoided treating induction part contact shower nozzle and cause cross infection's problem.
Description
Technical Field
The utility model relates to the technical field of disinfection machines, in particular to a disinfection machine.
Background
The main compounds commonly used as hand disinfectants are: the ozone water has strong oxidizability, can quickly kill bacteria and viruses, and can not cause pollution to the environment because all the ozone water is generated after reaction, so the ozone water is gradually approved and applied.
The shower nozzle or the nozzle that sprays ozone water among the correlation technique generally are the button, need the manual button of pressing, and are troublesome, and in the in-process of disinfecting, the shower nozzle or nozzle are touched very easily to the hand, have cross infection's risk.
SUMMERY OF THE UTILITY MODEL
Accordingly, the present invention is directed to a sterilizer, which generates ozone water by induction and adjusts a shape of a nozzle according to the induction to prevent a part to be induced from contacting the nozzle to cause cross infection.
In order to solve the above problems, embodiments of the present invention provide a sterilization apparatus including an ozone water generating assembly, a telescopic showerhead assembly, and an induction assembly; the ozone water generating assembly is connected with the telescopic spray head assembly, the induction assembly is arranged at the telescopic spray head assembly, and an induction distance is preset in the induction assembly;
the induction component induces an external environment according to a preset induction distance to generate an induction signal, and transmits the signal to the ozone water generation component and the telescopic spray head component respectively, the ozone water generation component controls ozone water to generate according to the signal, and the telescopic spray head component controls the spray head to stretch out according to the signal.
In some embodiments, the preset sensing distance L in the sensing assembly satisfies: l is1≤L≤L2(ii) a Wherein L is1The minimum distance L between the part to be sensed and the sensing component when the nozzle extends out2The maximum distance between the part to be sensed and the sensing component is the maximum distance when ozone water is generated.
In some embodiments, the retractable nozzle assembly comprises a nozzle controller, a nozzle, a storage tube and a retractable head sleeve, wherein the nozzle controller is connected with the sensing assembly, the nozzle is located in the retractable head sleeve, the retractable head sleeve is inserted into the storage tube, and the retractable head sleeve moves along the storage tube to extend and retract the nozzle.
In some embodiments, the ozone water generating assembly comprises a water storage unit, an electrolysis controller and a water pump, wherein an inlet of the electrolysis unit is communicated with the water storage unit, an outlet of the electrolysis unit is connected with the telescopic spray head assembly through the water pump, the electrolysis controller is connected with the electrolysis unit, and the electrolysis controller is further connected with the induction assembly and used for receiving signals of the induction assembly and controlling the electrolysis unit to work according to the signals.
In some embodiments, the electrolysis unit comprises a power supply, an electrolysis bath, and an electrolysis anode strip, an electrolysis cathode strip and an electrolysis exchange membrane which are positioned in the electrolysis bath, wherein one side of the electrolysis exchange membrane is in contact with the electrolysis anode strip, the other side of the electrolysis exchange membrane is in contact with the electrolysis cathode strip, the power supply is electrically connected with the electrolysis bath, and the power supply is also connected with an electrolysis controller.
In some embodiments, the electrolysis unit further comprises a water level detector, the water level detector is positioned in the electrolysis bath and is connected with the electrolysis controller, and the electrolysis controller controls the working state of the electrolysis unit according to the data detected by the water level detector.
In some embodiments, the water storage unit comprises a water inlet pipe, a water storage tank, a pipeline and an electric water pump arranged on the pipeline, one end of the water inlet pipe is connected with an external water source, the other end of the water inlet pipe is connected with the water storage tank, one end of the pipeline extends into the water storage tank, and the other end of the pipeline is connected with the electrolytic bath; the electric water pump is connected with the electrolysis controller, and the electrolysis controller controls the working state of the electric water pump according to the data detected by the water level detector.
In some embodiments, the sensing component comprises an infrared sensor.
In some embodiments, the disinfection machine further comprises a water receiving tray, wherein the water receiving tray is positioned below the telescopic spray head assembly and is used for collecting water drops generated in disinfection; the bottom of the water receiving tray is provided with a water outlet which is communicated with the outside through a pipeline.
In some embodiments, the disinfection machine further comprises a housing ozone water generation assembly, a telescopic sprayer assembly, a sensing assembly and a water pan which are all positioned in the housing, wherein one side of the housing close to the telescopic sprayer assembly is inwards sunken, the telescopic sprayer assembly is positioned at the top of the sunken position, and the water pan is positioned at the bottom of the sunken position.
Compared with the prior art, the sterilizing machine at least has the following beneficial effects:
when the part to be sensed is placed below the telescopic sprayer assembly to be disinfected, the sensing assembly senses a signal and transmits the signal to the ozone water generating assembly and the telescopic sprayer assembly respectively; the ozone water generating assembly receives the signal and then controls the generation of ozone water, and because the induction distance is arranged in the induction assembly, the part to be induced is determined to be required to be disinfected after the signal is received, and the ozone water generating assembly starts to work and generate ozone water, so that the ozone water can be prepared at any time, and the phenomenon that the ozone water is prepared in advance and loses part of performance due to instability is avoided;
and, control the shower nozzle and stretch out after flexible shower nozzle subassembly received this signal, because the signal that response subassembly itself received has certain scope (satisfies predetermined response distance promptly), this scope is eliminated and is treated the distance that response portion and flexible shower nozzle subassembly probably contacted, consequently the affirmation signal can not cause in this scope to treat that response portion contacts the shower nozzle, then the shower nozzle can stretch out this moment, has avoided treating response portion contact shower nozzle and has caused cross infection's problem.
The foregoing description is only an overview of the technical solutions of the present invention, and in order to make the technical solutions of the present invention more clearly understood and to implement them in accordance with the contents of the description, the following detailed description is given with reference to the preferred embodiments of the present invention and the accompanying drawings.
Drawings
FIG. 1 is a schematic diagram of a sterilizer provided in accordance with an embodiment of the present invention;
FIG. 2 is a schematic view of a retractable nozzle assembly of a sterilizer according to an embodiment of the present invention in an extended state of the nozzle;
FIG. 3 is a schematic view of a retractable nozzle assembly of a sterilizer according to an embodiment of the present invention in a retracted state;
fig. 4 is a flowchart of a control method of a sterilizer according to an embodiment of the present invention.
Wherein:
1. an ozone water generating assembly; 2. a retractable showerhead assembly; 3. an inductive component; 4. a water pan; 5. a housing; 11. a water storage unit; 12. an electrolysis unit; 13. an electrolysis controller; 14. a water pump; 21. a nozzle controller; 22. a spray head; 23. receiving a tube; 24. a retractable head sleeve; 111. a water inlet pipe; 112. a water storage tank; 113. a pipeline; 114. an electric water pump; 121. a power source; 122. an electrolytic cell; 123. electrolyzing the anode sheet; 124. electrolyzing the cathode sheet; 125. an electrolytic exchange membrane; 1221. and (7) an exhaust port.
Detailed Description
To further explain the technical means and effects of the present invention for achieving the intended purpose of the utility model, the following detailed description of the embodiments, structures, features and effects according to the present application will be given with reference to the accompanying drawings and preferred embodiments. In the following description, different "one embodiment" or "an embodiment" refers to not necessarily the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.
In the description of the present invention, it is to be understood that the terms "vertical", "lateral", "longitudinal", "front", "rear", "left", "right", "upper", "lower", "horizontal", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description of the present invention, and do not mean that the device or member to which the present invention is directed must have a specific orientation or position, and thus, cannot be construed as limiting the present invention.
In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.
The embodiment provides a sterilizing machine, as shown in fig. 1, the sterilizing machine includes ozone water generation subassembly 1, flexible shower nozzle subassembly 2 and response subassembly 3, and ozone water generation subassembly 1 is connected with flexible shower nozzle subassembly 2, and response subassembly 3 sets up in flexible shower nozzle subassembly 2 department, and has preset the sensing distance in the response subassembly 3.
The sensing assembly 3 senses the external environment according to a preset sensing distance to generate a sensing signal, and transmits the signal to the ozone water generation assembly 1 and the telescopic sprayer assembly 2 respectively, the ozone water generation assembly 1 controls ozone water according to the signal, and the telescopic sprayer assembly 2 controls the extension of a sprayer according to the signal.
Specifically, when the part to be sensed is placed below the telescopic sprayer assembly 2 to be disinfected, the sensing assembly 3 senses a signal and transmits the signal to the ozone water generating assembly 1 and the telescopic sprayer assembly 2 respectively; the ozone water generating assembly 1 receives the signal and then controls the generation of ozone water, and because the signal received by the induction assembly 3 is in a certain range, the induction part to be induced is determined to need to be disinfected after the signal is received, and at the moment, the ozone water generating assembly 1 starts to work and generates ozone water; control shower nozzle after flexible shower nozzle subassembly 2 received this signal and stretches out, because the signal that response subassembly 3 itself received has certain extent (satisfies predetermined sensing distance promptly), this scope has been eliminated and is waited the distance that response portion and flexible shower nozzle subassembly 2 probably contacted, consequently considers the signal and can not cause in this scope to wait that response portion contacts the shower nozzle, then the shower nozzle can stretch out this moment.
In a specific embodiment:
the preset induction distance L in the induction component 3 meets the following requirements: l is1≤L≤L2(ii) a Wherein L is1When the nozzle extends out, the minimum distance L between the part to be sensed and the sensing component 32The maximum distance between the part to be sensed and the sensing component 3 when ozone water is generated.
Thus, when the sensing component 3 can sense a signal, it is proved that the sensing component L satisfies: l is1≤L≤L2(ii) a At this time, the ozone water generating component 1 and the telescopic spray head component 2 respectively generate corresponding actions, namely, ozone water is manufactured and the spray head is extended out due to L1When the nozzle extends out, the minimum distance between the part to be sensed and the sensing component 3 is ensured, and under the condition, the contact risk possibly existing when the part to be sensed is too close to the nozzle is avoided; and, due to L2When ozone water is generated, the maximum distance between the part to be sensed and the sensing assembly 3 is ensured, and the interference of objects at a longer distance to the sensing assembly 3 is avoided.
In a specific embodiment:
as shown in fig. 1-3, the retractable nozzle assembly 2 includes a nozzle controller 21, a nozzle 22, a storage tube 23, and a retractable head cover 24, the nozzle controller 21 is connected to the sensing assembly 3, the nozzle 22 is located in the retractable head cover 24, the retractable head cover 24 is inserted into the storage tube 23, and the retractable head cover 24 moves along the storage tube 23 to extend and retract the nozzle 22.
Specifically, the nozzle 22 is in a telescopic state in an initial state, the sensing component 3 senses a signal and transmits the signal to the nozzle controller 21, and the nozzle controller 21 controls the telescopic head sleeve 24 to move along the accommodating pipe 23 to realize the extension of the nozzle 22; when the signal disappears, the head controller 21 controls the retractable head sleeve 24 to move in the opposite direction along the storage tube 23, thereby retracting the head 22.
More specifically, one side of the bottom of the retractable head cover 24 protrudes outward, a groove-shaped track is provided in the storage tube 23, and a driving mechanism is controlled by the nozzle controller 21, and acts on the storage tube 23 to rotate the storage tube 23, so that the retractable head cover 24 moves up and down along the groove-shaped track without rotating during the rotation of the storage tube 23, thereby enabling the nozzle 22 to retract along the storage tube 23.
In a specific embodiment:
the ozone water generating assembly 1 comprises a water storage unit 11, an electrolysis unit 12, an electrolysis controller 13 and a water pump 14, wherein an inlet of the electrolysis unit 12 is communicated with the water storage unit 11, an outlet of the electrolysis unit 12 is connected with the telescopic sprayer assembly 2 through the water pump 14, the electrolysis controller 13 is connected with the electrolysis unit 12, and the electrolysis controller 13 is also connected with the induction assembly 3 and used for receiving signals of the induction assembly 3 and controlling the electrolysis unit 12 to work according to the signals.
Thus, when the electrolytic controller 13 in the ozone water generating assembly 1 receives the signal of the induction assembly 3, the electrolytic unit 12 starts to operate to generate ozone water, which flows to the shower head 22 through the water pump 14; if the electrolytic controller 13 can receive the signal from the sensing component 3, the shower head controller 21 can receive the signal, and the shower head controller 21 controls the retractable head cover 24 to move along the receiving pipe 23 to extend the shower head 22, and at this time, ozone water is sprayed out through the shower head 22 to sterilize the portion to be sensed.
In a specific embodiment:
the electrolysis unit 12 comprises a power supply 121, an electrolysis bath 122, an electrolysis anode sheet 123, an electrolysis cathode sheet 124 and an electrolysis exchange membrane 125, wherein the electrolysis anode sheet 123, the electrolysis cathode sheet 124 and the electrolysis exchange membrane 125 are positioned in the electrolysis bath 122, one side of the electrolysis exchange membrane 125 is in contact with the electrolysis anode sheet 123, the other side of the electrolysis exchange membrane is in contact with the electrolysis cathode sheet 124, the power supply 121 is electrically connected with the electrolysis bath 122, and the power supply 121 is also connected with the electrolysis controller 13.
Specifically, when the power supply 121 is turned on to electrolyze water in the electrolytic bath 122, ozone is generated on the side of the electrolytic anode sheet 123, hydrogen is generated on the side of the electrolytic cathode sheet 124, the generated hydrogen can be discharged through the gas outlet 1221 provided on the electrolytic bath 122, and ozone dissolved in water is ozone water.
The ozone water is prepared by electrolyzing water, which is a convenient and low-cost method.
In a specific embodiment:
the electrolysis unit 12 further comprises a water level detector which is positioned in the electrolysis bath 122 and is connected with the electrolysis controller 13, and the electrolysis controller 13 controls the working state of the electrolysis unit 12 according to the data detected by the water level detector.
Specifically, in order to ensure that the electrolysis unit 12 can produce ozone water smoothly, the water level in the electrolysis tank 122 should cover at least the electrolysis anode sheet 123, the electrolysis cathode sheet 124 and the electrolysis exchange membrane 125, so that the minimum required water level is preset in the electrolysis controller 13, and when the water level detected by the water level detector does not reach the minimum water level requirement, the electrolysis unit 12 does not work, otherwise, the electrolysis unit 12 can work.
In a specific embodiment:
the water storage unit 11 comprises a water inlet pipe 111, a water storage tank 112, a pipeline 113 and an electric water pump 114 arranged on the pipeline 113, wherein one end of the water inlet pipe 111 is connected with an external water source, the other end of the water inlet pipe is connected with the water storage tank 112, one end of the pipeline 113 extends into the water storage tank 112, and the other end of the pipeline 113 is connected with the electrolytic bath 122; the electric water pump 114 is connected to the electrolysis controller 13, and the electrolysis controller 13 controls the operation state of the electric water pump 114 based on the data detected by the water level detector.
When the water level in the electrolytic bath 122 detected by the water level detector does not reach the minimum water level requirement, the electrolysis controller 13 controls the electric water pump 114 to work until the water level meets the requirement.
When the electric water pump 14 works, water in the water storage tank 112 is pumped into the electrolytic bath 122 along the pipeline 113 through the electric water pump 14; the water in the water storage tank 112 is from an external water source, which injects water into the water storage tank 112 through the water inlet pipe 111.
In a specific embodiment:
the sensing assembly 3 comprises an infrared sensor.
The infrared inductor senses the hand by means of infrared ray reflecting principle, and when the hand is in infrared area, the infrared ray from the infrared emitting tube is reflected to the infrared receiving tube and the signal processed by the microcomputer in the integrated circuit is sent to the pulse solenoid valve for transmitting or executing the next operation.
In this embodiment, the solenoid valve receives the signal and transmits the signal to the ozone water generating assembly 1 and the retractable showerhead assembly 2.
In a specific embodiment:
the sterilizer also comprises a water receiving tray 4, and the water receiving tray 4 is positioned below the telescopic spray head component 2 and is used for collecting water drops generated during sterilization; the bottom of the water receiving tray 4 is provided with a water outlet which is communicated with the outside through a pipeline.
Specifically, when the induction part is disinfected by ozone water, water drops are generated, and in order to avoid the pollution of the water drops to the environment, the water drops are collected through the water receiving disc 4; and the water outlet at the bottom of the water pan 4 is in a normally open state and is used for discharging the received water to the outside at any time.
In a specific embodiment:
the sterilizing machine further comprises a shell 5, an ozone water generating assembly 1, a telescopic sprayer assembly 2, a sensing assembly 3 and a water pan 4 which are all located in the shell 5, one side of the shell 5, which is close to the telescopic sprayer assembly 2, is inwards sunken, the telescopic sprayer assembly 2 is located at the top of the sunken part, and the water pan 4 is located at the bottom of the sunken part.
Specifically, the part of the casing 5 close to one side of the telescopic sprayer assembly 2 is inwards recessed, so that the casing 5 forms a concave structure which rotates 90 degrees, a notch is formed in the top end of the inwards recessed part and used for enabling the sprayer 22 to extend out, and the lower end of the inwards recessed part is provided with the water receiving tray 4.
More specifically, the infrared sensor is fixed to an inner surface of the inwardly recessed portion.
The working process of the disinfection machine provided by the embodiment is as follows:
in the initial state, the showerhead 22 is retracted within the housing 5 and the electrolysis unit 12 is not operated;
when the electrolysis controller 13 in the ozone water generating assembly 1 receives the signal of the sensing assembly 3, the water level detector transmits the detected water level in the electrolytic tank 122 to the electrolysis controller 13, when the water level does not reach the minimum water level requirement, the electrolysis controller 13 controls the electric water pump 114 to work, the water in the water storage tank 112 is pumped into the electrolytic tank 122 along the pipeline 113 through the electric water pump 14 until the water level meets the requirement;
when the water level meets the requirement, the electrolysis controller 13 controls the power supply 121 to be switched on, when water in the electrolytic cell 122 is electrolyzed, ozone is generated on one side of the electrolysis anode sheet 123, hydrogen is generated on one side of the electrolysis cathode sheet 124, the generated hydrogen can be discharged through an exhaust port 1221 arranged on the electrolytic cell 122, and the ozone dissolved in the water is ozone water; meanwhile, the sensing component 3 senses a signal and transmits the signal to the nozzle controller 21, and the nozzle controller 21 controls the telescopic head sleeve 24 to move along the accommodating pipe 23, so that the nozzle 22 extends out; the ozone water is sprayed out in an atomized form by the extrusion of the water pump 14 and the combined action of the spray head 22 for the disinfection of the user;
when the user finishes the disinfection and the sensing component 3 cannot sense the signal, the spray head controller 21 controls the telescopic head sleeve 24 to move along the accommodating pipe 23 in the opposite direction, so as to realize the contraction of the spray head 22; at the same time, the power supply 121 is disconnected, the electrolysis unit 12 stops operating, and the sterilizer returns to the initial state.
The present embodiment provides a control method of a sterilization machine, as shown in fig. 4, the control method of the sterilization machine includes:
s1, setting the sensing distance of the sensing component 3;
s2, the sensing component 3 senses external signals in real time;
s3, when the sensing component 3 senses the external signal, the signal is transmitted to the ozone water generating component 1 and the telescopic spray head component 2, after the ozone water generating component 1 and the telescopic spray head component 2 receive the signal, the ozone water generating component 1 works to generate ozone water, and the spray head of the telescopic spray head component 2 extends out.
Set up response distance of response subassembly 3, specifically do:
the induction distance L satisfies: l is1≤L≤L2(ii) a Wherein L is1When the nozzle extends out, the minimum distance L between the part to be sensed and the sensing component 32The maximum distance between the part to be sensed and the sensing component 3 when ozone water is generated.
Thus, when the sensing component 3 can sense a signal, it is proved that the sensing component L satisfies: l is1≤L≤L2(ii) a At this time, the ozone water generating component 1 and the telescopic spray head component 2 respectively generate corresponding actions, namely, ozone water is manufactured and the spray head is extended out due to L1When the spray head extends out, the minimum distance between the part to be sensed and the sensing component 3 is ensured, and under the condition, the contact risk possibly existing due to the fact that the part to be sensed is too close to the spray head is avoided; and, due to L2Is ozone waterWhen the sensor is used, the maximum distance between the part to be sensed and the sensing component 3 is the largest, so that the interference of an object at a longer distance to the sensing component 3 is avoided.
The control method of the sterilizing machine further comprises:
when the ozone water generating assembly 1 and the telescopic spray head assembly 2 do not receive signals, the ozone water generating assembly 1 does not work, and the spray head of the telescopic spray head assembly 2 is in a contraction state.
Therefore, when the induction part does not need to be disinfected, the spray head is always in the contraction state, and the influence of bacteria in the external environment on the spray head is avoided
After ozone water generation subassembly 1 and flexible shower nozzle subassembly 2 received the signal, ozone water generation subassembly 1 work produces ozone water, specifically is:
the water level detector works to transmit the water level in the electrolytic bath 122 detected in real time to the electrolytic controller 13;
when the water level does not reach the preset water level, the electrolysis controller 13 controls the electric water pump 114 to work until the water level reaches the preset water level;
when the water level reaches the preset level, the electrolysis controller 13 controls the electrolysis bath 122 to switch on the power supply 121, and the electrolysis unit 12 starts to operate to generate ozone water.
Specifically, in order to ensure that the electrolytic unit 12 can produce ozone water smoothly, the water level in the electrolytic tank 122 should at least cover the electrolytic anode plate 123, the electrolytic cathode plate 124 and the electrolytic exchange membrane 125, so that the lowest required water level is preset in the electrolytic controller 13, when the water level detected by the water level detector does not reach the lowest water level requirement, the electrolytic unit 12 does not work, and the electrolytic controller 13 controls the electric water pump 114 to work until the water level reaches the preset water level; on the contrary, the electrolysis controller 13 controls the electrolysis bath 122 to switch on the power supply 121, and the electrolysis unit 12 starts to operate to generate ozone water.
In summary, it is easily understood by those skilled in the art that the advantageous technical features described above can be freely combined and superimposed without conflict.
The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way, and any simple modification, equivalent change and modification made to the above embodiment according to the technical spirit of the present invention are still within the scope of the technical solution of the present invention.
Claims (10)
1. A sterilizing machine is characterized by comprising an ozone water generating assembly (1), a telescopic spray head assembly (2) and an induction assembly (3); the ozone water generating assembly (1) is connected with the telescopic spray head assembly (2), the induction assembly (3) is arranged at the telescopic spray head assembly (2), and an induction distance is preset in the induction assembly (3);
the induction component (3) induces an external environment according to a preset induction distance to generate an induction signal, and the signal is transmitted to the ozone water generation component (1) and the telescopic sprayer component (2) respectively, the ozone water generation component (1) controls the generation of ozone water according to the signal, and the telescopic sprayer component (2) controls the extension of the sprayer according to the signal.
2. A disinfection machine as claimed in claim 1, wherein said predetermined sensing distance L inside said sensing assembly (3) is such as to satisfy: l is1≤L≤L2(ii) a Wherein L is1When the nozzle extends out, the minimum distance L between the part to be sensed and the sensing component (3)2The maximum distance between the part to be induced and the induction component (3) is the maximum distance when ozone water is generated.
3. The disinfection machine according to claim 1, wherein the retractable nozzle assembly (2) comprises a nozzle controller (21), a nozzle (22), a storage tube (23) and a retractable head sleeve (24), the nozzle controller (21) is connected with the sensing assembly (3), the nozzle (22) is located in the retractable head sleeve (24), the retractable head sleeve (24) is inserted into the storage tube (23), and the retractable head sleeve (24) moves along the storage tube (23) to extend and retract the nozzle (22).
4. A disinfection machine as claimed in any one of claims 1-3, wherein said ozone water generating assembly (1) comprises a water storage unit (11), an electrolysis unit (12), an electrolysis controller (13) and a water pump (14), wherein the inlet of said electrolysis unit (12) is connected to said water storage unit (11), the outlet of said electrolysis unit (12) is connected to said telescopic spray assembly (2) via said water pump (14), said electrolysis controller (13) is connected to said electrolysis unit (12), said electrolysis controller (13) is further connected to said induction assembly (3) for receiving the signal of said induction assembly (3) and controlling said electrolysis unit (12) to operate according to said signal.
5. A disinfection machine as claimed in claim 4, wherein said electrolysis unit (12) comprises a power supply (121), an electrolysis cell (122) and an electrolysis anode strip (123), an electrolysis cathode strip (124) and an electrolysis exchange membrane (125) located inside said electrolysis cell (122), said electrolysis exchange membrane (125) being in contact with said electrolysis anode strip (123) on one side and with said electrolysis cathode strip (124) on the other side, said power supply (121) being electrically connected to said electrolysis cell (122), said power supply (121) being further connected to an electrolysis controller (13).
6. A disinfection machine as claimed in claim 5, characterized in that said electrolysis unit (12) further comprises a water level detector, said water level detector being located in the electrolysis cell (122), said water level detector being connected to the electrolysis controller (13), said electrolysis controller (13) controlling the operating state of the electrolysis unit (12) on the basis of the data detected by the water level detector.
7. The disinfection machine as claimed in claim 6, wherein said water storage unit (11) comprises a water inlet pipe (111), a water storage tank (112), a pipeline (113) and an electric water pump (114) arranged on said pipeline (113), one end of said water inlet pipe (111) is connected with an external water source, the other end is connected with said water storage tank (112), one end of said pipeline (113) extends into said water storage tank (112), the other end is connected with said electrolytic tank (122); the electric water pump (114) is connected with the electrolysis controller (13), and the electrolysis controller (13) controls the working state of the electric water pump (114) according to the data detected by the water level detector.
8. A disinfection machine as claimed in any one of claims 1-3, characterized in that said sensing assembly (3) comprises an infrared sensor.
9. A disinfection machine as claimed in any one of claims 1-3, characterized in that said machine further comprises a drip tray (4), said drip tray (4) being located below said telescopic jet assembly (2) for collecting water drops produced during disinfection; the bottom of the water receiving tray (4) is provided with a water outlet which is communicated with the outside through a pipeline.
10. A disinfection machine as claimed in claim 9, further comprising a housing (5), said ozone water generating assembly (1), said telescopic showerhead assembly (2), said sensing assembly (3) and said water pan (4) all being located within said housing (5), one side of said housing (5) near said telescopic showerhead assembly (2) being inwardly recessed, said telescopic showerhead assembly (2) being located at the top of said recess, said water pan (4) being located at the bottom of said recess.
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202123040065.3U CN216603778U (en) | 2021-12-06 | 2021-12-06 | Sterilizing machine |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202123040065.3U CN216603778U (en) | 2021-12-06 | 2021-12-06 | Sterilizing machine |
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| CN216603778U true CN216603778U (en) | 2022-05-27 |
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| CN202123040065.3U Active CN216603778U (en) | 2021-12-06 | 2021-12-06 | Sterilizing machine |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| WO2023236448A1 (en) * | 2022-06-09 | 2023-12-14 | 广东康柏力医疗器械有限公司 | Disinfection and handwashing machine |
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2021
- 2021-12-06 CN CN202123040065.3U patent/CN216603778U/en active Active
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| WO2023236448A1 (en) * | 2022-06-09 | 2023-12-14 | 广东康柏力医疗器械有限公司 | Disinfection and handwashing machine |
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