KR20210091111A - Electronic sterilizing humidifier - Google Patents

Abstract

Disclosed is a sterilizing humidifier using a ceramic honeycomb heating element. The present invention provides a humidifier characterized in that a ceramic honeycomb heating element is installed at a discharge port of a general ultrasonic humidifier to perform sterilization process by heating atomized particles to 100 degrees or more. The ceramic honeycomb heating element can heat the atomized particles, generated by the ultrasonic humidifier, to 100 degrees or more with low power consumption of about 100 Watt and can perfectly sterilize microorganisms contained in the atomized particles because a contact area with the atomized particles is wide due to a honeycomb structure. The present invention may provide the sterilizing humidifier that has very low power consumption as compared with a conventional heating type humidifier and solves a sanitary problem caused by the general ultrasonic humidifier and in particular, may be used as the sterilizing humidifier necessary for the storage of exhibited items vulnerable to microorganisms.

Description

Electric Sterilization Humidifier {ELECTRONIC STERILIZING HUMIDIFIER}

The present invention relates to a sterilization type humidifier, and more particularly, to a humidifier in which a ceramic honeycomb heating element is installed at the outlet of a general ultrasonic humidifier to heat atomized particles to 100 degrees or more for sterilization.

In winter, along with the development of the heating system, the indoor air becomes dry and respiratory diseases are induced in the elderly. Therefore, a humidifier is often used to control humidity.

Humidifiers are roughly classified into heated humidifiers and ultrasonic humidifiers according to humidification methods.

The heated humidifier is a method that naturally sprays the water vapor generated by heating the water in the atomization tank to a high temperature indoors. The ultrasonic method uses a vibrator that vibrates the water in the atomization tank with ultrasonic waves to make water fine particles and spray it into the room. method.

The heating-type humidifier not only requires a high-capacity heater to evaporate water, but also has disadvantages in that atomization particles are not sufficiently generated.

Ultrasonic humidifier is a method of generating ultrasonic waves by the ultrasonic vibrator included in the water container and splitting water into small particles and blowing them out. Bacteria are propagated by contact with the spray, and these bacteria are scattered in the air along with the spray, which can rather seriously harm the health of the elderly and infirm.

As a result of using sterilizing detergents to solve this problem, rather than causing respiratory-related toxicity, social problems such as many casualties occurred. In addition, heating-type humidifiers currently on the market are sanitary-safe because they generate atomized particles by boiling water, but there is a problem in that power consumption is large because a lot of energy is required to increase the discharge amount. In addition, there is also a disadvantage in that the efficiency of the existing heating element used to boil water is low, so that the rate of hot steam is slow.

It is an object of the present invention to provide a sterilization humidifier using a ceramic honeycomb heating element that has the sterilization ability, which is an advantage of a heated humidifier, and improves the discharge rate of atomized particles by rapidly heating water particles with low power consumption.

On the other hand, the user compares the desired humidity set by the user with the current indoor humidity, and as a result of the comparison, the ultrasonic wave is generated strongly or weakly or the heater is heated strongly or weakly to generate water vapor depending on the difference between the desired humidity and the indoor humidity. The purpose of the present invention is to provide a rapid humidification method in the ultrasonic humidification method and the heater humidification method so that the user can reach the desired humidity more quickly.

To this end, a ceramic honeycomb heating element was installed at the atomization particle outlet of the ultrasonic humidifier, and the atomized particles generated by the ultrasonic wave passed through the honeycomb and heated.

The ceramic honeycomb heating element has a cylindrical structure with a diameter of 20 mm and a length of 40 mm ^{, consisting of 52 square grids of 2 x 2 mm 2} , mixed with a composition of 80% SiC, 10% Si, and 10% Carbon, and extruded to 1500 in a vacuum furnace. After reaction sintering for 1 hour, silver electrodes were applied to the upper and lower parts to prepare the product. The resistance of the manufactured heating element was 484 ohms.

On the other hand, the configuration of the conventional humidification control device is shown. A key input unit for setting desired humidity and overall function selection of the humidifier, a humidity sensing unit sensing indoor humidity, and receiving information about indoor humidity from the humidity sensing unit, and determining the current indoor humidity using the user's key input unit A control unit that controls the humidification operation until the desired humidity set by operation is reached, a heater driving unit that outputs a constant voltage according to the control of the control unit, and a predetermined heat source by operating with the voltage output from the heater driving unit to generate water vapor It is composed of a heater for generating , an ultrasonic wave generator for generating ultrasonic waves of a certain frequency under the control of the controller, and a vibrator for generating water vapor by vibrating by the ultrasonic waves output from the ultrasonic wave generator, The basic structure of the humidifier is omitted to avoid overlapping explanations.

The operation of the conventional humidification control device configured as described above will be described as follows.

First, when the user operates the key input unit to turn on the humidifier, the controller controls the heater driving unit and the ultrasonic wave generating unit to perform the humidification operation.

Accordingly, the heater driving unit supplies a constant voltage to the heater under the control of the control unit so that water supplied from the water supply pipe is heated by the heat source generated by the heater to generate water vapor, and the ultrasonic generating unit is controlled by the control unit. By generating ultrasonic waves of a certain frequency and vibrating the vibrator, water vapor is generated.

On the other hand, when the humidification operation is performed as described above, the humidity sensing unit senses the humidity in the room where the humidifier is installed, and supplies the sensed information to the control unit.

At this time, when the user sets the desired humidity by operating the key input unit, the control unit compares the indoor humidity detected by the humidity sensing unit with the desired humidity set by the user, and as a result of the comparison, the indoor humidity is higher than the desired humidity set by the user. When it is determined, the humidifying operation is stopped by turning off the heater driving unit and the ultrasonic generating unit, and if it is determined that the indoor humidity is lower than the desired humidity set by the user as a result of the comparison, the heater driving unit and the ultrasonic generating unit are controlled so that the humidifying operation is further performed for a predetermined time .

Then, after a predetermined time has elapsed, the current indoor humidity and the desired humidity are compared again, and if the current indoor humidity is higher than the desired humidity, the humidification operation is stopped. Even at this time, if the current indoor humidity is lower than the desired humidity, the humidifying operation is further performed for a predetermined time, and then the control operation is repeatedly performed to control the current indoor humidity to reach the desired humidity.

However, the conventional control method as described above always controls the humidification operation with a constant control amount until the current indoor humidity reaches the desired humidity set by the user so that a certain amount of water vapor is generated. There was a problem in that the power consumption of the product increased as the time required to reach the humidity increased.

Therefore, the present invention for solving the above problems compares the desired humidity set by the user and the current indoor humidity, and as a result of the comparison, generates an ultrasonic wave strongly or weakly, or a heater strongly or strongly depending on the difference between the desired humidity and the indoor humidity. An object of the present invention is to provide an ultrasonic humidification method and a rapid humidification method in the heater humidification method that can reach the desired humidity set by the user more quickly by heating it lightly to generate water vapor.

In the specific method of the present invention for achieving the above object, when the desired humidity is set, the first process of comparing the current indoor humidity with the desired humidity, and as a result of the comparison of the first process, the humidification operation is stopped if the indoor humidity is greater than the desired humidity If the indoor humidity is less than the desired humidity, the second process of detecting the humidification operation control information (K) by performing the calculation of 'desired humidity-indoor humidity', and the humidification operation control information detected by the second process ( K) and the third process of controlling the heater driving unit and the ultrasonic wave generating unit in at least three modes according to the comparison result of the table values set in the memory unit.

The third process includes a fourth process of generating water vapor by turning on only the heater when the humidification operation control information K detected in the second process is less than or equal to 10% of the preset table value, and the second process. The fifth process of generating an appropriate amount of water vapor by turning on the heater and controlling the ultrasonic generator in the weak mode when the humidification operation control information (K) detected in is greater than 10% and less than 30% of the preset table value And, if the humidification operation control information K detected in the second process is greater than 30% of the preset table value, the heater is turned on and the ultrasonic generator is controlled in the strong mode to generate a large amount of water vapor. It is characterized by progressing through the process.

According to the present invention, it is possible to provide a hygienic and economical humidifier that can obtain a sterilization effect by heating the atomizing particles to a high temperature of 100 degrees or more even with a low power consumption of 100 Watt. The ceramic heating element has a large contact area with the atomizing particles due to the honeycomb structure, so that it heats the atomized particles quickly and effectively, so an excellent sterilization effect is expected.

1 is a diagram schematically illustrating a sterilization humidifier using a ceramic honeycomb heating element according to an embodiment of the present invention.
2 is a view showing components of a ceramic honeycomb heating element according to an embodiment of the present invention.
Figure 3 shows a flowchart for controlling a conventional humidification control device.
4 shows an embodiment of the circuit configuration applied to the rapid humidification method of the present invention.
5 is a flowchart illustrating the rapid humidification method of the present invention.
6 illustrates an embodiment of table values stored in a memory unit.

Hereinafter, the present invention for achieving the above object will be described in detail with reference to FIGS. 1 and 2 .

To this end, a ceramic honeycomb heating element 10 was installed in the atomization particle outlet 20 of the ultrasonic humidifier 30 of FIG. 1 , and the atomized particles generated by ultrasonic waves passed through the honeycomb 50 of FIG. 2 and heated.

The ceramic honeycomb heating element has a cylindrical structure with a diameter of 20 mm and a length of 40 mm ^{, consisting of 52 square grids of 2 x 2 mm 2} , mixed with a composition of 80% SiC, 10% Si, and 10% Carbon, and extruded to 1500 in a vacuum furnace. After reaction sintering for 1 hour, the silver electrodes 6 were applied to the upper and lower parts to prepare. The resistance of the manufactured heating element was 484 ohms.

On the other hand, Figure 3 shows the configuration of a conventional humidification control device. A key input unit (1) for setting desired humidity and overall function selection of the humidifier, a humidity sensing unit (2) for sensing indoor humidity, and receiving information about indoor humidity from the humidity sensing unit (2), A control unit 3 that controls the humidification operation until the current indoor humidity reaches the desired humidity set by the user's operation of the key input unit 1, and a heater driving unit that outputs a constant voltage according to the control of the control unit 3 (4) and a heater 5 that operates with the voltage output from the heater driving unit 4 to generate a predetermined heat source to generate water vapor, and generates ultrasonic waves of a predetermined frequency under the control of the control unit 3 It is composed of an ultrasonic wave generator 6 and a vibrator 7 that vibrates by ultrasonic waves output from the ultrasonic generator 6 to generate water vapor. omitted.

The operation of the conventional humidification control device configured as described above will be described as follows.

First, when the user operates the key input unit 1 to turn on the humidifier, the controller 3 controls the heater driving unit 4 and the ultrasonic wave generating unit 6 to perform the humidification operation.

Accordingly, the heater driver 4 supplies a constant voltage to the heater 5 under the control of the controller 3 so that the water supplied from the water supply pipe is heated by the heat source generated by the heater 5 to generate water vapor. In addition, the ultrasonic generator 6 generates ultrasonic waves of a certain frequency under the control of the controller 3 and vibrates the vibrator 7 to generate water vapor.

On the other hand, when the humidification operation is performed as described above, the humidity sensing unit 2 senses the humidity in the room where the humidifier is installed, and supplies the sensed information to the control unit 3 .

At this time, when the user operates the key input unit 1 to set the desired humidity, the control unit 3 compares the indoor humidity sensed by the humidity sensing unit 2 with the desired humidity set by the user, and as a result of the comparison, the indoor humidity If it is determined that the humidity is higher than the desired humidity set by the user, the heater driving unit 4 and the ultrasonic generator 6 are turned off to stop the humidification operation, and as a result of the comparison, if it is determined that the indoor humidity is lower than the desired humidity set by the user, a predetermined The heater driving unit 4 and the ultrasonic wave generating unit 6 are controlled so that the humidification operation is further performed for a period of time.

Then, after a predetermined time has elapsed, the current indoor humidity and the desired humidity are compared again, and if the current indoor humidity is higher than the desired humidity, the humidification operation is stopped. Even at this time, if the current indoor humidity is lower than the desired humidity, the humidifying operation is further performed for a predetermined time, and then the control operation is repeatedly performed to control the current indoor humidity to reach the desired humidity.

However, the conventional control method as described above always controls the humidification operation with a constant control amount until the current indoor humidity reaches the desired humidity set by the user so that a certain amount of water vapor is generated. There was a problem in that the power consumption of the product increased as the time required to reach the humidity increased.

Therefore, the present invention for solving the above problems compares the desired humidity set by the user and the current indoor humidity, and as a result of the comparison, generates an ultrasonic wave strongly or weakly, or a heater strongly or strongly depending on the difference between the desired humidity and the indoor humidity. An object of the present invention is to provide an ultrasonic humidification method and a rapid humidification method in the heater humidification method that can reach the desired humidity set by the user more quickly by heating it lightly to generate water vapor.

In the specific method of the present invention for achieving the above object, when the desired humidity is set, the first process of comparing the current indoor humidity with the desired humidity, and as a result of the comparison of the first process, the humidification operation is stopped if the indoor humidity is greater than the desired humidity If the indoor humidity is less than the desired humidity, the second process of detecting the humidification operation control information (K) by performing the calculation of 'desired humidity-indoor humidity', and the humidification operation control information detected by the second process ( K) and the third process of controlling the heater driving unit 4 and the ultrasonic wave generating unit 6 in at least three modes according to the comparison result of the table values set in the memory unit 13 is performed.

The third process includes a fourth process of generating water vapor by turning on only the heater when the humidification operation control information K detected in the second process is less than or equal to 10% of the preset table value, and the second process. The fifth process of generating an appropriate amount of water vapor by turning on the heater and controlling the ultrasonic generator in the weak mode when the humidification operation control information (K) detected in is greater than 10% and less than 30% of the preset table value And, if the humidification operation control information K detected in the second process is greater than 30% of the preset table value, the heater is turned on and the ultrasonic generator is controlled in the strong mode to generate a large amount of water vapor. It is characterized by progressing through the process.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to FIGS. 4 and 5 .

4 shows an embodiment of the circuit configuration applied to the rapid humidification method of the present invention.

A key input unit 11 for on/off control of the humidifier and setting the desired humidity, a humidity sensing unit 12 for detecting the humidity in the room where the humidifier is installed and supplying it to the control unit 14, and a predetermined value for controlling the humidification operation When the user sets the desired humidity with the memory unit 13 storing the table value, the humidification control information (K) is detected by comparing and calculating the set desired humidity and the indoor humidity, and the detected humidification control information (K) It is composed of a controller 14 that controls the heater driving unit 4 and the ultrasonic generator 6 so that the indoor humidity can reach the desired humidity as quickly as possible according to the table value (%) corresponding to , and the same components as in the prior art. The same code was used to avoid duplicate explanations.

4 is a flowchart for explaining the rapid humidification method of the present invention. As shown in this figure, the rapid humidification control method according to the present invention is a first process in which the user operates the key input unit 11 to turn on the humidifier. After the desired humidity is set by manipulating the key input unit 11 , the control unit 14 compares the desired humidity with the indoor humidity sensed by the humidity sensing unit 12 .

In the second process, if it is determined that the indoor humidity is higher than the desired humidity as a result of the comparison of the control unit 14 in the first process, the heater driving unit 4 and the ultrasonic wave generating unit 6 are maintained in an off state to control the humidification operation not to be performed. In the first process, if it is determined that the indoor humidity is lower than the desired humidity as a result of the comparison of the control unit 14, 'desired humidity - indoor humidity' is calculated to detect the humidification operation control information (K).

In the third process, after searching to which part of the table value stored in the memory unit 13 the humidification operation control information K detected in the second process belongs, the heater driving unit 4 is turned on/off according to the search result. and controlling the ultrasonic generator 6 in the strong/weak mode so that the indoor humidity can reach the desired humidity as quickly as possible.

And, in the third process, if the humidification operation control information K detected in the second process is less than 10% of the table value stored in the memory unit 13, only the heater driving unit 4 is turned on to operate the heater 5. When the humidification operation control information (K) detected in the fourth process of generating water vapor by the heating operation and the second process is greater than 10% and less than 30% of the table value stored in the memory unit 13, the heater driving unit ( 4) is turned on so that water vapor is generated by the heating operation of the heater 5, and the ultrasonic generator 6 is operated in a weak mode to generate water vapor by the vibration of the vibrator 7 And, if the humidification operation control information K detected in the second process is greater than 30% of the table value stored in the memory unit 13, the heater driving unit 4 is turned on, and the ultrasonic generator 6 is set to the strong mode. It proceeds to the sixth process in which water vapor is generated by the heating operation of the heater 5 and a large amount of water vapor is generated by the strong vibration of the vibrator 7 due to the generation of strong ultrasonic waves.

The operation of the rapid humidification method of the present invention made as described above will be described with reference to the accompanying FIGS. 4 to 6 .

First, when the user operates the key input unit 11 to turn on the humidifier and set the desired humidity, the control unit 14 compares the desired humidity set by the user with the indoor humidity sensed by the humidity sensor 12 . do.

As a result of the comparison, if it is determined that the current indoor humidity is higher than the desired humidity set by the user, the control unit 14 maintains the heater driving unit 4 and the ultrasonic wave generating unit 6 in an off state.

That is, the humidification operation is not executed.

However, when it is determined that the current indoor humidity is lower than the desired humidity set by the user as a result of the comparison, the control unit 14 detects the humidification operation control information K through the calculation process of 'desired humidity-indoor humidity'.

Then, the detected humidification operation control information (K), that is, the difference (K) between the desired humidity and the indoor humidity is compared with a table value stored in the memory unit 13, and the detected humidification operation control information (K) is obtained. Detects the table value to which it belongs.

The table value stored in the memory unit 13 is set through a number of experiments as shown in FIG. 5, and the percentage (%) is calculated as the difference (K) between the desired humidity and the indoor humidity is large and small. applied, and this table value is an example.

On the other hand, when a table value for the detected humidification operation control information K is detected, the control unit 14 controls the heater driving unit 4 and the ultrasonic wave generating unit 6 according to the detected value to set the desired indoor humidity. Humidity can be reached as quickly as possible, and the operation will be described in more detail as follows.

First, if the humidification operation control information K is less than 10% of the table value, the humidification operation control information K is less than 10% of the table value. It means that the difference between humidity and indoor humidity is smaller than '10', so it means that there is not a huge difference in humidity.

Accordingly, the control unit 14 turns on only the heater driving unit 4 to generate water vapor by the heat generated by the heater 5 so that the indoor humidity reaches the desired humidity.

Second, if the humidification operation control information (K) is greater than 10% and less than 30% of the table value, it is shown in FIG. 5 that the humidification operation control information (K) is greater than 10% and less than 30% of the table value. Taking the table as an example, it means that the difference between the desired humidity and the indoor humidity is greater than '10' and less than '30', so it means that a somewhat large difference in humidity remains.

Accordingly, the controller 14 turns on the heater driving unit 4 to generate water vapor by the heat generated by the heater 5 , and at the same time controls the ultrasonic generator 6 to a weak mode to generate weak ultrasonic waves.

As described above, when a weak supersonic difference is generated in the ultrasonic generator 6, the vibrator 7 vibrates weakly, so a small amount of water vapor is generated and the water vapor generated by the heating operation of the heater 5 is added. The indoor humidity will quickly reach the desired humidity.

Third, if the humidification operation control information (K) is greater than 30% of the table value, the humidification operation control information (K) is greater than 30% of the table value, as shown in FIG. 5, the difference between the desired humidity and the indoor humidity is greater than '30', so it means that there is a very large difference in humidity.

Accordingly, the control unit 14 turns on the heater driving unit 4 to generate water vapor by the heat generated by the heater 5 , and at the same time controls the ultrasonic generator 6 to a strong mode to generate strong ultrasound.

As described above, when strong ultrasonic waves are generated from the ultrasonic generator 6, the vibrator 7 vibrates strongly, so a large amount of water vapor is generated and added to the water vapor generated by the heating operation of the heater 5. The indoor humidity with a large difference in humidity with respect to the desired humidity will reach the desired humidity quickly.

As described above, the present invention compares the desired humidity set by the user with the current indoor humidity, and as a result of the comparison, generates ultrasonic waves strongly or weakly or heats the heater strongly or weakly according to the difference between the desired humidity and the indoor humidity. It is a rapid humidification method in the ultrasonic humidification method and the heater humidification method that allows the user to reach the desired humidity set by the user more quickly by generating water vapor.

When the heater driving unit 4 and the ultrasonic generator 6 are turned off through the control unit 14, a signal is applied to the ceramic honeycomb heating element, and the ceramic honeycomb heater is also placed in the off state.

10: ceramic honeycomb heating element (heating element)
20: outlet
30: ultrasonic humidifier
40: power
50: honeycomb
60: silver electrode
4: Heater driving part
5: Heater
6: Ultrasonic generator
7: Oscillator
11: key input
12: humidity sensor
13: memory unit
14: control unit

Claims (5)

A heater including a ceramic honeycomb heating element is formed in the atomization particle discharge port,
a memory unit for storing table values for humidification operation control;
heater driving unit;
an ultrasonic wave generator for generating ultrasonic waves;
When the desired humidity is set, humidification control information (K) is detected by comparing and calculating the desired humidity with the indoor humidity, and the indoor humidity is calculated according to the table value (%) corresponding to the detected humidification control information (K). a control unit for reaching a desired humidity; and
and a humidity sensing unit that senses the indoor humidity and supplies it to the control unit,
An ultrasonic sterilization humidifier capable of reaching the desired humidity by controlling the amount of water vapor generated from the heater according to a difference between the desired humidity and the indoor humidity. According to claim 1,
The control method of the ultrasonic humidifier includes: a first step of comparing the current indoor humidity with the desired humidity when the desired humidity is set;
As a result of comparison in the first process, if the indoor humidity is greater than the desired humidity, the humidification operation is not executed. a second process to do; and
It proceeds to the third process of controlling the heater and the ultrasonic generator in three modes according to the comparison result of the humidification operation control information (K) detected by the second process and the table value set in the memory unit,
An ultrasonic sterilization humidifier in which atomized particles generated through the humidification method are heated by the ceramic honeycomb heating element. According to claim 1,
The ceramic honeycomb heating element is produced by mixing the composition of SiC 80%, Si 10%, and Carbon 10%, extruding and reaction sintering in a vacuum furnace, and heating atomized particles to a high temperature of 100 degrees or more. Ultrasonic sterilization humidifier. 3. The method of claim 2,
The three modes include a fourth process of generating steam by turning on only the heater when the humidification operation control information (K) detected in the second process is less than or equal to 10% of a preset table value; If the humidification operation control information (K) detected in step 2 is greater than 10% and less than 30% of the preset table value, the heater is turned on and the ultrasonic generator is controlled in the weak mode to generate water vapor. ; And when the humidification operation control information (K) detected in the second process is greater than 30% of the preset table value, the heater is turned on and the ultrasonic generator is controlled in the strong mode to generate water vapor, which is the sixth process of ultrasonic sterilization. humidifier. 3. The method of claim 2,
In step 2, when it is determined that the indoor humidity is higher than the desired humidity as a result of the comparison of the control unit in the first step, the second step is an ultrasonic sterilization humidifier that controls the humidifying operation not to be performed by maintaining the heater driving unit and the ultrasonic generating unit in an off state.

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