CN111773528A - Integrated hand automatic temperature measurement sterilizer - Google Patents

Abstract

The invention discloses an integrated automatic temperature measurement hand disinfector, which comprises a shell, wherein a container is arranged in the shell, a disinfection area is arranged on the shell, an induction probe, a temperature measurement probe and a nozzle assembly are arranged on the shell wall of the disinfection area, and the nozzle assembly is communicated with the container; the inductive probe is used for detecting whether a detected object enters the disinfection area or not, the temperature measuring probe is used for detecting the temperature of the detected object entering the disinfection area, and the nozzle is used for spraying disinfectant on the detected object entering the disinfection area; and the control module is used for receiving the sensing signal of the sensing probe, sending a spraying instruction to the nozzle, processing the data of the temperature measuring probe and outputting the data to the display unit. The temperature measurement and the disinfection are integrated in the shell, the shell is provided with a disinfection area, when a hand enters the disinfection area and is sensed by the sensing probe, the control module acquires data of the temperature measurement probe, processes the data and displays the detected temperature of the human body; meanwhile, the hands are sterilized. The device is simple and high in integration level; small volume, low cost and flexible arrangement.

Description

Integrated hand automatic temperature measurement sterilizer

Technical Field

The invention belongs to a human body detection and disinfection technology, and particularly relates to an integrated human body hand temperature measurement and disinfection device.

Background

With the improvement of self health consciousness of people, the requirements of disinfection and cleaning of hands and detection of body temperature of people are normalized. The existing body temperature detection and hand disinfection are respectively carried out, and in the aspect of temperature measurement, the temperature is measured by automatic temperature measurement equipment or by a worker through handheld equipment; in the aspect of disinfection, a mobile disinfection station is arranged for disinfection of people going in and out or manual disinfection of disinfection liquid carried by workers. The temperature measurement and the disinfection process are separated in the mode, and the operation process is complicated.

In the conventional CN1961967A sterilizer and the control method thereof, whether the environmental conditions are suitable for the growth of microorganisms is detected, and if the environmental conditions are suitable, the sterilizer is started to generate a bactericide for sterilization; the device is obviously not suitable for temperature measurement and disinfection of human body, especially hand.

Disclosure of Invention

The invention aims to provide an integrated automatic hand temperature measuring and disinfecting instrument to realize the simultaneous temperature measurement of a human body and the disinfection of hands.

The technical scheme of the invention is as follows: the integrated automatic hand temperature measuring and sterilizing instrument comprises a shell, wherein a container is arranged in the shell, a sterilizing area is arranged on the shell, an induction probe, a temperature measuring probe and a nozzle assembly are arranged on the shell wall of the sterilizing area, and the nozzle assembly is communicated with the container; the induction probe is used for detecting whether a detected object enters the disinfection area or not, the temperature measuring probe is used for detecting the temperature of the detected object entering the disinfection area, and the nozzle assembly is used for spraying disinfectant on the detected object entering the disinfection area; the shell is internally provided with a control module for receiving a sensing signal of the sensing probe, sending a spraying instruction to the nozzle assembly, processing data of the temperature measuring probe and outputting the data to the display unit.

The further optimized technical proposal is that the induction probe comprises an infrared photoelectric switch; the infrared photoelectric switch is respectively connected with the power supply control switch of the power supply module and the processor of the control module.

The further optimized technical scheme is that the temperature measuring probe comprises an infrared temperature measuring sensor; the infrared temperature measurement sensor is connected with the processor of the control module and provides temperature parameters.

The technical scheme of further optimization is that the nozzle assembly comprises a liquid storage cavity, a liquid outlet is arranged in the liquid storage cavity, and a reticular ultrasonic atomization sheet is arranged at the liquid outlet.

The further optimized technical scheme is that a filtering ring net is arranged at the liquid outlet in the liquid storage cavity.

The further optimized technical scheme is that the filtering ring net and the reticular ultrasonic atomization sheet are coaxially arranged.

The technical scheme of further optimization is that pipelines are respectively arranged at the upper part and the lower part of the container, and the upper pipeline and the lower pipeline are respectively communicated with the upper part and the lower part of the liquid storage cavity.

The further optimized technical scheme is that the temperature sensor further comprises an alarm module, wherein the alarm module is connected with the control module and used for judging that the temperature of the measured object exceeds a set value at the control module and sending an alarm signal.

The further optimized technical scheme is that the reticular ultrasonic atomization sheet is electrically connected with an ultrasonic driving circuit, and the ultrasonic driving circuit is electrically connected with the control module.

The further optimized technical scheme is that the disinfection area comprises a concave part which is arranged on the shell and is concave to the inner wall of the shell, and the concave part forms a space capable of accommodating hands.

The further optimized technical proposal is that the shell wall at the upper part of the depressed part is provided with an induction probe and a temperature measuring probe; the inner part of the concave part is provided with a nozzle component on the shell wall below the induction probe or/and the temperature measuring probe.

The temperature measurement and the disinfection are integrated in the shell, the shell is provided with a disinfection area, and after a hand enters the disinfection area and is sensed by the sensing probe, the control module acquires data of the temperature measurement probe, processes the data and displays the detected temperature of the human body; meanwhile, after the hand is sensed, the nozzle is given an instruction, and disinfectant is sprayed to the hand to disinfect the hand. The device is simple and high in integration level; manpower resources are saved, the personnel contact probability is reduced, and the virus propagation risk is reduced; the device has small volume, low cost and flexible arrangement, and can be widely applied to various occasions such as hotels, restaurants, families, offices and the like; the micro-net ultrasonic atomization sheet atomizes the disinfectant and then sprays out the disinfectant, so that the hand area is thoroughly disinfected in a targeted manner, the coverage effect is good, and the disinfectant such as alcohol is saved.

Drawings

Fig. 1 is a schematic diagram of an integrated hand automatic temperature measurement sterilizer.

Fig. 2 shows an operation state machine of the integrated hand automatic temperature measurement sterilizer.

Fig. 3 is a schematic structural diagram 1 of the integrated hand automatic temperature measurement sterilizer.

Fig. 4 is a schematic structural diagram of an integrated hand automatic temperature measurement sterilizer 2.

FIG. 5 is a schematic view of the connection between the disinfecting liquid container and the ultrasonic atomizing watering can.

Fig. 6 is a schematic view of a micro-mesh ultrasonic atomization sheet and a filtering ring network of an ultrasonic atomization sprinkling can

Detailed Description

The following detailed description is provided for the purpose of explaining the claimed embodiments of the present invention so that those skilled in the art can understand the claims. The scope of the invention is not limited to the following specific implementation configurations. It is intended that the scope of the invention be determined by those skilled in the art from the following detailed description, which includes claims that are directed to this invention.

For the implementation of the above technical solution, the housing is of any shape with a cavity and is composed of a housing wall, and the housing wall 10 includes a housing cover to open or close the cavity. A container 7-3 (also called as a disinfectant container) is arranged in the shell and is used for containing disinfectant. Such as alcohol. The container can be a hollow structure enclosed by the container wall and the shell wall; or a hollow structure which is completely and independently finished by the container wall and is connected with the shell wall.

A sterilization zone 11 is provided on the housing. The sterilization zone 11 may be a planar zone set directly at the surface of the housing wall. The induction probe, the temperature measuring probe and the nozzle assembly are all arranged on the shell wall of the plane area.

In this embodiment, as shown in fig. 3 and 4, the disinfecting area 11 is a recessed portion formed on the housing wall and extending toward the interior of the housing, the recessed portion forms a space for accommodating a hand, and the disinfecting liquid is sprayed onto the area 11-1, into which the hand is inserted during temperature measurement and disinfection. The container 7-3 is arranged on the side of the recess or in the housing around the recess. A disinfectant filling opening 7-3.1 of the container 7-3 is arranged on the wall of the shell.

In the implementation, the shell wall of the upper part 11-2 of the concave part is provided with an induction probe and a temperature measuring probe. The inductive probe is an infrared photoelectric switch 2-1, the temperature measuring probe is an infrared temperature measuring sensor 4-1, the interior of the concave part is positioned in the inductive probe, and a nozzle assembly 7-2 is arranged on a shell wall below the temperature measuring probe. In an embodiment, a plurality (four) of nozzle assemblies are provided around the recess. The sprayed disinfectant is concentrated in the disinfectant spraying area 11-1 in the space which can contain the hands and is formed by the sunken parts, so that the disinfectant is prevented from being splashed to the outside, and the waste of the disinfectant is reduced.

The bottom of the depressed part is provided with a liquid collecting groove 11-3, the liquid collecting groove 11-3 is communicated with a liquid discharge hole 11-4 on the shell, and the liquid discharge hole 11-4 is connected with a hole cover 11-5.

A liquid level visible window 7-3.2 is arranged on the shell at the position of the container 7-3.

The control systems of the instrument are all arranged in the shell; as shown in fig. 1, the power module 1 is included, the power module includes an external power supply 1-1, a battery power supply 1-2 and a power supply control switch 1-3, and the external power supply 1-1 may be powered by an external low-voltage dc adapter, for example, a USB interface. The external power supply 1-1 and the battery power supply 1-2 are connected in parallel and supply power to the outside through the power supply control switch 1-3. The external power supply 1-1 and the battery power supply 1-2 are mutually redundant, and the temperature-measuring sterilizer can work normally as long as one set of power supply works normally. The power module is arranged at the lower part of the shell.

The inductive probe 2 comprises an infrared photoelectric switch 2-1. The power supply input end of the infrared photoelectric switch 2-1 is connected with the power supply output end of the power supply control switch 1-3, and the control output end is connected with the control input end of the power supply control switch 1-3 and the processor 3-1 of the control module 3.

The control module 3 includes 1 processor 3-1 and its attached circuits. The power supply input end of the processor 3-1 is connected with the power supply output end of the power supply control switch 1-3. The processor 3-1 can be realized by a single chip microcomputer, an ARM or other control chips.

The temperature measuring probe 4 comprises an infrared temperature measuring sensor 4-1, the number of the temperature measuring probes can be increased if temperature measuring points need to be increased, and the additionally arranged temperature measuring probes can be arranged in the disinfection area 11 or outside the disinfection area. The power supply input end of the infrared temperature measurement sensor 4-1 is connected with the power supply output end of the power supply control switch 1-3, and the signal output end is connected with the processor 3-1. The signal connection between the infrared temperature measurement sensor 4-1 and the processor 3-1 can adopt an SPI interface or other interfaces.

The display module 5 comprises an LCD display screen 5-1. The signal input end of the LCD display screen 5-1 is connected with the processor 3-1. Other types of display screens may also be used for the LCD display screen 5-1.

The display screen 5-1 is arranged on the wall of the housing, in the embodiment the display screen 5-1 is arranged on the wall of the housing above the recess.

The alarm module 6 comprises a buzzer 6-1. The buzzer 6-1 is connected with the processor 3-1 and receives the control signal sent by the processor.

The disinfection module 7 comprises a container, a driving circuit and a nozzle assembly; the nozzle assembly can be composed of a valve communicated with the container and a nozzle; the valve is controlled to be opened by the control unit, and the disinfectant is sprayed by the nozzle. The same solution for the nozzle assembly is micronet ultrasonic atomization.

In the embodiment shown in fig. 3, 4, 5 and 6, four nozzle assemblies are arranged in the sensing area. The nozzle assembly 7-2 comprises a liquid storage cavity 7-2-1, a liquid outlet 7-2-4 is arranged in the liquid storage cavity, and a micro-grid ultrasonic atomization sheet 7-2-3 is arranged at the position of the liquid outlet 7-2-4; a filtering ring net 7-2-2 is arranged at the liquid outlet in the liquid storage cavity and used for reducing the pressure difference between the inner side and the outer side of the micro-net ultrasonic atomization sheet 7-2-3 and preventing the disinfectant from leaking outwards through the atomization sheet.

In the embodiment, 4 ultrasonic driving circuits 7-1 are correspondingly arranged; the container 7-3 is arranged above the nozzle assembly 7-2, the ultrasonic driving circuit 7-1 is connected with the micro-grid ultrasonic atomizing sheet 7-2-3 of the nozzle assembly 7-2, and drives the micro-grid ultrasonic atomizing sheet 7-2-3 to spray atomized particles; 4 nozzle assemblies 7-2 are configured, are symmetrically arranged in front, back, left and right directions, and spray atomized disinfectant to respectively disinfect the front and back sides of the hands; as shown in fig. 4, the disinfectant container 7-3 is installed above the nozzle assembly 7-2, and is connected to the nozzle assembly 7-2 through two pipelines, one pipeline is connected to the bottom to provide the disinfectant required for atomization, and the other pipeline is connected to the top to maintain pressure balance.

The temperature measurement sterilizer mainly comprises three working modes: as shown in fig. 2;

1) standby mode: after power-on initialization, the induction probe 2 enters a standby mode and is continuously powered by the power module 1; under the temperature measurement mode or the disinfection mode, if the induction probe 2 can not detect the object for 20 seconds continuously, the power supply module 1 is triggered to stop outputting, the standby mode is entered, and the other modules except the induction probe 2 lose power, so that the power consumption is saved.

2) Temperature measurement mode: in a standby mode, when the induction probe 2 detects an object, the starting output of the power supply module 1 is triggered to supply power to the control module 3, the temperature measuring probe 4, the display module 5, the alarm module 6 and the disinfection module 7, and the temperature measuring mode is started; in the sterilization mode, the object is detected again, and the temperature measurement mode is also entered. After entering the temperature measurement mode, the control module 3 controls the temperature measurement probe 4 to start measuring the temperature and sends a temperature signal to the display module 7 for display; and meanwhile, judging whether the temperature of the object to be measured exceeds a set value or not, and controlling an alarm module 6 to send out an alarm signal if the temperature of the object to be measured exceeds the set value.

3) A disinfection mode: temperature measurement is normally finished (the temperature is in a reasonable range) and the inductive probe 2 continuously detects an object, the temperature measurement mode enters a disinfection mode, the control module 3 controls the disinfection module 7 to spray a proper amount of mist-shaped disinfectant to realize hand disinfection, and prompt information is displayed on the display module after the disinfection is finished.

Claims (11)

1. An integrated automatic temperature measuring and sterilizing instrument for hands comprises a shell, wherein a container is arranged in the shell, and the instrument is characterized in that a sterilizing area is arranged on the shell, an induction probe, a temperature measuring probe and a nozzle assembly are arranged on the shell wall of the sterilizing area, and the nozzle assembly is communicated with the container; the inductive probe is used for detecting whether a detected object enters the disinfection area or not, the temperature measuring probe is used for detecting the temperature of the detected object entering the disinfection area, and the nozzle is used for spraying disinfectant on the detected object entering the disinfection area; and the control module is used for receiving the sensing signal of the sensing probe, sending a spraying instruction to the nozzle, processing the data of the temperature measuring probe and outputting the data to the display unit.

2. The integrated automatic hand temperature measuring and disinfecting instrument as claimed in claim 1, wherein the sensing probe comprises an infrared photoelectric switch; the infrared photoelectric switch is respectively connected with the power supply control switch of the power supply module and the processor of the control module.

3. The integrated automatic hand temperature measuring and disinfecting instrument as claimed in claim 1, wherein the temperature measuring probe comprises an infrared temperature measuring sensor; the infrared temperature measurement sensor is connected with the processor of the control module and provides temperature parameters.

4. The integrated automatic temperature measuring and sterilizing instrument for hands as claimed in claim 1, wherein the nozzle assembly comprises a liquid storage cavity, a liquid outlet is arranged in the liquid storage cavity, and a mesh-shaped ultrasonic atomization plate is arranged at the liquid outlet.

5. The integrated automatic temperature measuring and sterilizing instrument for hands as claimed in claim 4, wherein a filtering ring net is arranged at the liquid outlet in the liquid storage cavity.

6. The integrated automatic hand temperature measuring and sterilizing instrument of claim 4, wherein the filtering ring net and the mesh-shaped ultrasonic atomization sheet are coaxially arranged.

7. The integrated automatic temperature measuring and sterilizing instrument for hands of claim 1, wherein the upper part and the lower part of the container are respectively provided with a pipeline, and the upper pipeline and the lower pipeline are respectively communicated with two sides of the liquid storage cavity.

8. The integrated automatic temperature measuring and sterilizing instrument for hands as claimed in claim 1, further comprising an alarm module connected to the control module for sending an alarm signal when the control module determines that the temperature of the object exceeds a set value.

9. The integrated automatic temperature measuring and sterilizing instrument for hands of claim 4, wherein the reticular ultrasonic atomization sheet is electrically connected with the ultrasonic driving circuit, and the ultrasonic driving circuit is electrically connected with the control module.

10. The integrated automatic temperature measuring and sterilizing instrument for hands as claimed in claim 4, wherein the sterilizing area comprises a recess formed on the housing and facing the inner wall of the housing, the recess forming a space for accommodating the hands.

11. The integrated automatic temperature measuring and sterilizing instrument for hands of claim 10, wherein the shell wall at the upper part of the concave part is provided with an induction probe and a temperature measuring probe; the inner part of the concave part is provided with a nozzle component on the shell wall below the induction probe or/and the temperature measuring probe.

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