KR102603586B1 - humidifier module, humidifier apparatus having the same and control method for the same - Google Patents

Abstract

The present invention relates to a humidifier module, a humidifier device having the same, and a method of controlling the humidifier module. More specifically, it relates to a humidifier module installed in a medical patient's breathing apparatus (1), a humidifier device including the same, and control of the humidifier module. It's about method.
The present invention includes a supply pipe (100) in which a gas tube (10) is coupled at both ends to form a passage (S1) through which the gas supplied to the patient passes; A housing portion 200 in which an internal space S2 is formed and a communication port 210 is formed so that the internal space S2 communicates with the passage passage S1; It may include an atomization unit 300 that is installed in the internal space (S2) and atomizes water supplied from the outside into fine humidifying particles and supplies it to the passage passage (S1).

Description

Humidifier module, humidifier device having the same and control method of the humidifier device {humidifier module, humidifier apparatus having the same and control method for the same}

The present invention relates to a humidifier module, a humidifier device having the same, and a method of controlling the humidifier module. More specifically, it relates to a humidifier module installed in a breathing apparatus of a medical patient, a humidifier device including the same, and a method of controlling the humidifier module. will be.

A humidifier is an electric device that controls indoor humidity by spraying or evaporating water to create water vapor. It plays a role in increasing humidity. It mainly includes ultrasonic vibration type, which vibrates water using ultrasonic waves to emit finely divided water droplets, and electric type. There is a heating method that boils water and releases water vapor, and a method that evaporates naturally by blowing natural wind or a fan on a medium soaked in water.

In particular, in the case of a heated humidifier that boils water with electricity and releases water vapor, sterilization is automatic because it boils water, and it is a humidification method that can be heated and has the least side effects.

Accordingly, medical humidifiers that are installed in the patient's breathing apparatus to maintain appropriate humidity in the gas supplied to the patient through the breathing apparatus are mainly heated humidifiers that boil water and emit water vapor.

Meanwhile, in the past, a medical humidifier was used in which the supply pipe that supplies gas to the patient through the breathing device passes through a humidifier and boils distilled water through the humidifier to adjust the humidity of the gas supplied to the patient. However, in this method, the humidifier There is a problem that condensation occurs while reaching the patient's respiratory tract.

In other words, the humidity of the gas is controlled through a humidifier while the gas is supplied through the supply pipe from the breathing device that supplies gas to the patient. As the distance from the humidifier to the patient's respiratory tract increases, condensation occurs depending on the external temperature environment. There is a problem that arises.

As described above, when condensation occurs in the supply pipe, as the inside of the pipe becomes humid, bacteria proliferate, contaminating the supplied gas, and are harmful to the patient's respiratory system.

In addition, as condensation occurs in the supply pipe, there is a problem that continuous maintenance, such as removing water accumulated due to moisture condensation, is required.

Meanwhile, in order to solve this problem, the conventional medical humidifier is equipped with a heating wire in the supply pipe to prevent condensation from occurring in the supply pipe depending on the external environment by increasing the temperature inside the supply pipe. However, a heating wire is installed inside the supply pipe. There is a problem in that the production process increases and the production cost increases as this has to be done.

In addition, conventional medical humidifiers used gas that heats the inside of the supply pipe to prevent condensation in the supply pipe, etc., but there is a problem in that secondary problems such as safety and contamination problems occur due to the high heat of the gas.
(Patent Document 1) KR 10-1479545 B1
(Patent Document 2) KR 10-2019-0016936 A

The purpose of the present invention is to provide a humidifier module that is easy to use and easy to maintain, a humidifier device including the same, and a control method for the humidifier module in order to solve the above problems.

The present invention was created to achieve the object of the present invention as described above, and the present invention is to form a passage (S1) through which the gas supplied to the patient passes by combining a gas tube (10) at both ends. A supply pipe (100); A housing portion 200 in which an internal space S2 is formed and a communication port 210 is formed so that the internal space S2 communicates with the passage passage S1; Disclosed is a humidifier module including an atomizing unit 300 installed in the internal space (S2), which atomizes water supplied from the outside into fine humidifying particles and supplies the water to the passage passage (S1).

The housing portion 200 may be provided in a direction perpendicular to the gas movement direction among the supply pipes 100.

The atomizing unit 300 includes a filter unit 310 installed to cover the communication port 210 in the internal space S2; a heater unit 320 that is installed spaced apart from the filter unit 310 to form a heating space (S3) between the filter unit 310 and heats water supplied to the heating space (S3); It may include a supply pipe 330 that receives water from the outside and supplies it to the heating space (S3).

The filter unit 310 includes a filter 311 that forms the heating space S3 and allows the humidifying particles to pass through, and a filter plate 312 installed in the communication port 210 to support the filter 311. ) may include.

The heater unit 320 includes a heater plate 321 installed parallel to the filter unit 310 to form the heating space S3, and a heating wire unit installed on the heater plate 321 to generate heat. It may include (322).

The heater unit 320 may further include a sealing member 400 installed at the edge to seal the heating space S3 to seal it.

It may include a temperature sensor 500 installed in the heater unit 320 to measure the temperature of the heater unit 320.

In addition, the present invention includes a gas tube (10), one end of which is connected to the patient, and the other end of which is connected to a gas supply device that supplies gas to the patient; A humidifier module (20) according to any one of claims 1 to 7, which is installed in the gas tube (10) and supplies humidifying particles to the gas supplied to the patient through the gas tube (10). ; Disclosed is a humidifier device including a control unit 30 that is connected to the humidifier module 20 and controls the humidity of the gas by controlling the humidifier module 20.

The humidifier module 20 may be provided adjacent to the patient side of the gas tube 10.

The control unit 30 may measure the temperature of the gas within the humidifier module 20 and control the humidity of the gas.

The control unit 30 can control the humidity of the gas by measuring the temperature of the heater unit 320 for generating humidifying particles in the humidifier module 20.

In addition, the present invention includes a gas tube (10), one end of which is connected to the patient, and the other end of which is connected to a gas supply device that supplies gas to the patient; A humidifier module (20) installed in the gas tube (10) to supply humidifying particles to the gas supplied to the patient through the gas tube (10); A control method of a humidifier device including a control unit 30 that is connected to the humidifier module 20 and controls the humidity of the gas by controlling the humidifier module 20, wherein the A measurement step (S100) of directly or indirectly measuring temperature and humidity; A humidifier device control method including a humidity control step (S200) of controlling the humidity of the gas by controlling the humidifier module 20 through the control unit 30 based on the measured temperature and humidity of the gas is disclosed.

In the measurement step (S100), the temperature of the heater unit 320 may be measured based on the temperature sensor 500 installed in the heater unit 320.

The humidifier module, the humidifier device provided with the same, and the control method of the humidifier module according to the present invention are installed on the patient's side among the supply pipes that supply gas to the patient through the breathing device, and minimize the distance from the humidifier to the patient's respiratory tract within the supply pipe. It has the advantage of minimizing condensation and preventing contamination problems such as bacteria.

Furthermore, the humidifier module, the humidifier device including the same, and the control method of the humidifier module according to the present invention are modularized into a relatively light and simple structure and installed on the patient side among the supply pipes that supply gas to the patient, so that the humidified gas reaches the patient. It has the advantage of being able to precisely control temperature and humidity by minimizing the influence of the external temperature environment.

In addition, the humidifier module, the humidifier device including the same, and the control method of the humidifier module according to the present invention are inexpensive to manufacture because additional components such as heating wires for maintaining a constant temperature inside the supply pipe from the external temperature environment can be omitted, The manufacturing process is simplified and has the advantage of being easy to manufacture.

In addition, the humidifier module, the humidifier device including the same, and the control method of the humidifier module according to the present invention prevent moisture condensation inside the supply pipe, so maintenance such as removing stagnant water inside is not required, so maintenance This has the advantage of reducing costs and increasing convenience of use.

In addition, the humidifier module, the humidifier device including the same, and the control method of the humidifier module according to the present invention enable precise control of humidity, which is directly and closely affected by temperature, by controlling the temperature of the heater for heating the distilled water inside. There is an advantage.

In addition, the humidifier module, the humidifier device including the same, and the control method of the humidifier module according to the present invention enable precise temperature measurement by using a temperature sensor that measures the room temperature of the heater to precisely control the humidity of the gas supplied to the patient. There is an advantage in that it is possible to precisely control the humidity of the gas based on this.

In addition, the humidifier module, the humidifier device including the same, and the control method of the humidifier module according to the present invention omit the additional configuration for maintaining the temperature inside the supply pipe, and are coupled to the supply pipe without a separate body including a water tank, so that the patient can use the humidifier module. Since it is installed on the gas path supplied to the system, it has the advantage of being lighter in weight and simpler in composition compared to conventional systems.

1 is a conceptual diagram schematically showing a humidifier device including a humidifier module according to the present invention.
Figure 2 is a perspective view showing the humidifier module of Figure 1.
Figure 3 is an exploded perspective view showing the configuration of the humidifier module of Figure 1.
Figure 4 is a cross-sectional view showing the internal configuration of the humidifier module of Figure 1.
Figure 5 is an enlarged cross-sectional view showing the heating portion of the humidifier module of Figure 1.

Hereinafter, the humidifier module according to the present invention, the humidifier device equipped with the same, and the control method of the humidifier module will be described with reference to the attached drawings.

As shown in Figure 1, the humidifier device according to the present invention includes a gas tube (10) with one end connected to the patient side and the other end connected to a gas supply device (2) for supplying gas to the patient; A humidifier module (20) according to any one of claims 1 to 7, which is installed in the gas tube (10) and supplies humidifying particles to the gas supplied to the patient through the gas tube (10). ; It is connected to the humidifier module 20 and includes a control unit 30 that controls the humidity of the gas by controlling the humidifier module 20.

Here, the gas according to the present invention is a gas supplied to the patient and is supplied to the patient's breathing apparatus (1) through the gas supply device (2) and delivered to the patient. It can be included.

Meanwhile, the gas according to the present invention is supplied to the patient through the gas supply device 2, and any configuration is applicable as long as it is subject to humidity control.

The gas tube 10 is configured such that one end is connected to the patient side and the other end is connected to the gas supply device 2 that supplies gas to the patient, and various configurations are possible.

For example, the gas tube 10 is a first gas tube whose one end is connected to the gas supply device 2 and the other end is connected to the humidifier module to supply the gas delivered from the gas supply device 2 to the humidifier module. (11) and a second gas tube (12), one end of which is connected to the humidifier module and the other end of which is connected to the breathing device (1) on the patient side, and which delivers the humidity-controlled gas to the patient through the humidifier module. there is.

The gas tube 10 can be of any configuration as long as it is a conventionally disclosed medical gas delivery tube.

The humidifier module 20 is installed in the gas tube 10 and supplies humidifying particles to the gas supplied to the patient through the gas tube 10, and various configurations are possible.

At this time, the humidifier module 20 is installed in the gas tube 10 and controls the humidity by supplying humidifying particles to the gas supplied to the patient, thereby minimizing the distance through which the humidity-controlled gas is delivered to the patient, thereby maintaining the gas tube ( 10) It can prevent the proliferation of bacteria and minimize the impact from the external environment.

That is, the humidifier module 20 is installed adjacent to the patient's breathing apparatus 1 and the patient side of the gas tube 10, so that the humidity-controlled gas can be delivered to the patient in the shortest distance.

Meanwhile, the humidifier module 20 can precisely control the humidity of the gas supplied to the patient.

For example, the humidifier module 20 includes a gas tube 10 coupled to both ends, a supply pipe 100 forming a passageway S1 through which the gas supplied to the patient passes, and an internal space S2. a housing portion 200 in which a communication opening 210 is formed so that the internal space S2 communicates with the passage passage S1; It is installed in the internal space (S2) and includes an atomization unit (300) that atomizes water supplied from the outside into fine humidifying particles and supplies it to the passage passage (S1).

In addition, the humidifier module 20 may include a temperature sensor 500 that is installed in the heater unit 320, which will be described later, and measures the temperature of the heater unit 320.

The supply pipe 100 has a gas tube 10 coupled to both ends to form a passage S1 through which the gas supplied to the patient passes, and various configurations are possible.

For example, the supply pipe 100 has a passage passage (S1) through which gas passes, an inlet 110 through which gas flows in at one end, and an outlet 120 through which gas with completed humidity control is discharged at the other end. can be formed.

The supply pipe 100 may have a circular cross-section, and the inlet 110 to which the first tube 11 is connected and the outlet 120 to which the second tube 12 is connected have different cross-sectional areas. can be formed.

More specifically, in the supply pipe 100, the radius of the inlet 110 to which the first tube 11 is connected may be formed to be larger than the radius of the outlet 120 to which the second tube 12 is connected.

In addition, the supply pipe 100 is open on one side corresponding to the communication port 210 so that the passage passage S1 communicates with the internal space S2 of the housing portion 200, which will be described later, through the communication port 210. An opening 130 may be formed.

At this time, the supply pipe 100 may communicate with the internal space S2 of the housing portion 200 provided on one side and the passage passage S1 through the opening 130 and the communication hole 210, thereby By supplying the humidifying particles generated through the internal space (S2) of the housing portion (200) to the passage passage (S1) through the communication port (210) and the opening opening (130), the humidifying particles are supplied to the patient through the passage passage (S1). The humidity of the gas can be adjusted.

At this time, the opening 130 may have a rectangular shape corresponding to the planar shape of the heater unit 320 and the filter unit 310, which will be described later, and the edges in the direction parallel to the moving direction of the gas on the plane are It can be formed longer than the edge perpendicular to the direction of movement of the aircraft.

Through this, it is possible to more easily control the humidity of the gas by securing a long time and position for the gas supplied to the patient through the passage S1 to be affected by the heater unit 320 and the filter unit 310.

The housing portion 200 is configured to have an internal space S2 and a communication port 210 to communicate with the internal space S2 and the passage S1, and various configurations are possible.

The housing portion 200 may be provided in a direction perpendicular to the direction of gas movement among the supply pipes 100.

That is, the housing portion 200 may be provided to extend radially in a direction perpendicular to the direction of gas movement among the supply pipes 100.

For example, the housing portion 200 includes a communication port 210 formed by opening one side to communicate with the supply pipe 100, a main body portion provided in the vertical direction of the gas movement direction among the supply pipe 100, and ( 220), and may include an open portion 230 that is coupled to the upper side of the main body 220 to form an internal space (S2).

In addition, the housing part 200 may include an inlet part 240 formed in the main body part 220 and installed with a supply pipe 330, which will be described later and which supplies water from the outside to the inside.

The communication port 210 is formed by opening one side of the main body 220 to communicate with the supply pipe 100, and various configurations are possible.

For example, the communication port 210 is formed at a contact portion of the main body 220 with the supply pipe 100, so that it can communicate with the opening 130 formed on one side of the supply pipe 100, The internal space (S2) of the housing part (200) and the passage (S1) of the supply pipe (100) can be communicated through a filter part (310) to be described later.

The communication opening 210 may have a rectangular shape in plan to correspond to the opening 130 described above, and may be formed so that its long side corresponds to the moving direction of the gas.

The main body 220 is provided in the supply pipe 100 in a direction perpendicular to the direction of gas movement, and various configurations are possible.

For example, the main body portion 220 may be formed integrally with the supply pipe 100 and may be provided on one side of the supply pipe 100, for example, extending upward to form an internal space S2.

Meanwhile, of course, the main body 220 can be installed by coupling to the supply pipe 100.

The main body 220 may include a bottom 221 on which the above-described communication hole 210 is formed, and a step 222 formed to have a step at the edge of the bottom 221. .

Additionally, the main body portion 220 may include a side wall portion 223 formed at the outermost edge for coupling with the cover portion 230, which will be described later.

That is, the main body portion 220 has a communication opening 210 formed, a bottom portion 221 whose bottom is integrally or contact-coupled with the supply pipe 100, and a step upward from the edge of the bottom portion 221. It may include a step portion 222 formed to have a step portion 222 and a side wall portion 223 formed at the edge for coupling with the covering portion 230.

The cover portion 230 is joined at the upper side of the main body portion 220 to form an internal space S2, and various configurations are possible.

For example, the covering portion 230 may be coupled to the main body 220 from the upper side so as to cover and surround the side wall portion 223 formed on the side of the main body 220. In this case, as will be described later. The upper surface of the sealing plate and the upper surface of the side wall portion 223 may be contacted to form an internal space (S2).

The inlet portion 240 is formed in the main body portion 220 and is installed with a supply pipe 330 that supplies water from the outside to the inside, and various configurations are possible.

For example, the inlet part 240 is a part where the supply pipe 330, one end of which is connected to an external water supply device and the other end of which is connected to the main body 220, is installed in the main body 220, and the supply pipe 330 is connected to the main body 220. It can be formed through processing to correspond to one end of the pipe 330.

More specifically, the inlet part 240 communicates with a connection part 241 to which the supply pipe 330 is connected, and from the connection part 241 to an internal space (S2), specifically a heating space (S3) to be described later. It may include a delivery unit 242 that delivers water supplied from the supply pipe 330 to the heating space (S3).

Meanwhile, as another example, it goes without saying that the inlet portion 240 can be formed not only through processing of the above-described main body portion 220, but also through the installation of a separate pipe.

In addition, the housing portion 200 may further include a cover portion 250 that covers the entire cover portion 230 and at least a portion of the main body portion 220.

The cover part 250 is installed to cover the entire cover part 230 and at least a portion of the main body part 220, and various configurations are possible.

For example, the cover part 250 may be installed on the outer side of the cover part 230 from the upper side to surround the side of the cover part 230, and is provided to surround the side of the cover part 230. It may extend downward to cover at least a portion of the main body 220.

Meanwhile, the cover part 250 may include a plurality of protrusions 251 that protrude toward the cover part 230 to form an insulating space between the cover part 250 and the cover part 230 .

That is, the cover part 250 can be installed in contact with the cover part 230 and the plurality of protrusions 251, thereby forming an insulating space between the cover part 230 and the main body part 220. You can.

As a result, safety can be improved and promoted when the user operates the humidifier module through insulation between the heater unit 320 and the cover unit 230 through which heat is transferred.

The atomization unit 300 is installed in the internal space (S2) and atomizes water supplied from the outside into fine humidifying particles and supplies it to the passageway (S1). Various configurations are possible.

At this time, the atomization unit 300 is installed in the internal space (S2) and atomizes the water particles received from the outside through ultrasonic waves into accelerated particles and supplies them to the passage passage (S1), or naturally atomizes the water particles using a fan, etc. It may be configured to evaporate.

As another example, the atomization unit 300 may be configured to heat water particles received from the outside using a heater, thereby atomizing them into accelerated particles and supplying them to the passage S1.

More specifically, the atomization unit 300 includes a filter unit 310 installed to cover the communication port 210 in the internal space S2; A heater unit 320 is installed spaced apart from the filter unit 310 to form a heating space (S3) between the filter unit 310 and heats the water supplied to the heating space (S3); It may include a supply pipe 330 that receives and supplies water from the outside to the heating space (S3).

The filter unit 310 is installed to cover the communication port 210 in the internal space S2, and various configurations are possible.

That is, the filter unit 310 separates the inner space (S2) from the passageway (S1) by covering the communication port (210) and the opening port (130) in the inner space (S2). ) and the passage passage (S1) may be configured to pass atomized humidifying particles and block water particles.

For example, the filter unit 310 includes a filter 311 that forms a heating space (S3) and allows humidifying particles to pass through, and a filter plate 312 installed in the communication port 210 to support the filter 311. ) may include.

The filter 311 forms a heater unit 320 and a heating space S3, which will be described later, and allows humidifying particles to pass through, and various configurations are possible.

For example, the filter 311 is installed spaced apart from the lower side of the heater unit 320 to form a heating space (S3) between the heater unit 320 and the water supplied to the heating space (S3). The passage of particles is blocked, and humidifying particles that are heated and atomized through the heater unit 320 can selectively pass through.

At this time, the filter 311 may be made of a membrane material.

The filter plate 312 is installed in the communication port 210 to support the filter 311, and various configurations are possible.

For example, the filter plate 312 is installed in the communication port 210 and can support the filter 311 located on the upper side. More specifically, the shape of the filter 311 is changed by continuously passing humidifying particles. Deformation can be prevented from the lower side.

In addition, the filter plate 312 is formed of a mesh material so that the humidifying particles that have passed through the filter 311 can pass through and be supplied to the passage passage (S1) through the communication port 210 and the opening port 130. You can.

That is, the filter plate 312 may be composed of frames for supporting the filter 311 and a mesh material installed between the frames.

In addition, the filter plate 312 has a filter plate protrusion 313 that protrudes upward from one side toward the heater plate 321 to form a sealed heating space (S3) between the heater plate 321 and the heater plate 321, which will be described later. ) may additionally be included.

The filter plate protrusion 313 may partially protrude upward to form the side of the heating space (S3), and is formed on both sides of the filter plate 312 to be sealed by being combined with a heater plate 321 to be described later. A heated space (S3) can be formed.

The heater unit 320 is installed spaced apart from the filter unit 310 to form a heating space (S3) between the filter unit 310 and heats the water supplied to the heating space (S3), and is configured to heat water supplied to the heating space (S3). Configuration is possible.

That is, the heater unit 320 forms a heating space (S3) between the filter unit 310 and supplies the heating space (S3) through the configuration of the supply pipe 330 and the inlet 240, which will be described later. By heating the water, water particles can be atomized to form humidifying particles.

For example, the heater unit 320 includes a heater plate 321 installed parallel to the filter unit 310 to form a heating space S3, and a heating wire installed on the heater plate 321 to generate heat. It may include part 322.

More specifically, the heater unit 320 is provided in a rectangular shape corresponding to the filter unit 310, and is installed in parallel at a predetermined distance upward from the filter unit 310, thereby creating a heating space (S3). can be formed.

At this time, the heating space (S3) is a space where water supplied from the outside through a supply pipe 330, which will be described later, is temporarily stored, and is located between the heater unit 320, that is, the heater plate 321 and the filter unit 310. can be formed.

Accordingly, the heater unit 320 applies heat to the water particles provided in the heating space (S3), thereby evaporating the water so that the atomized humidifying particles pass through the filter unit 310 and are supplied to the passage passage (S1). can do.

The heater plate 321 is formed in a rectangular shape corresponding to the filter unit 310, that is, the filter 311, and is installed in parallel at regular intervals on the upper side of the filter 311, and has various configurations. possible.

In particular, the heater plate 321 is made of a metal material with excellent heat conductivity so that the heat transmitted through the heating wire portion 322, which will be described later, can be well transmitted to the heating space (S3) and the water particles within the heating space (S3). It can be formed, and more specifically, aluminum, stainless steel, etc. can be used.

The heating element 322 is formed on one surface of the heater plate 321 to generate heat that is transmitted to water particles, and various configurations are possible.

For example, the heating wire unit 322 may be provided to have a certain pattern on one surface of the heater plate 321 in order to increase heat conduction efficiency through the heater plate 321.

Meanwhile, the heating element 322 may be formed on the upper surface of the heater plate 321, and more specifically, may be formed on the surface opposite to the heating space (S3) of the heater plate 321 to generate heat, Heat can be transferred through the heater plate 321.

In addition, the heater unit 320 may further include a sealing member 400 installed at the edge to seal the heating space S3 to seal it.

The sealing member 400 is installed at the edge of the heater plate 321 to seal the heating space S3 and prevent water particles inside from leaking to the outside.

That is, the sealing member 400 is a member that is in close contact with the edge of the heater plate 321 and the bottom 221 of the main body 220, and is formed between the heater plate 321 and the filter portion 310. The heating space (S3) can be sealed so that water particles inside do not leak to the outside.

Meanwhile, in this case, the sealing member 400 may be installed on the step portion 222 formed to have a step upward at the bottom portion 221 of the main body portion 220.

In addition, the heater unit 320 may further include a sealing plate 323 that is formed to correspond to the edge of the heater plate 321 and is coupled to the upper side of the heater plate 321.

The sealing plate 323 is designed to prevent water particles in the heating space S3 from leaking to the outside, and various configurations are possible.

For example, the sealing plate 323 is partially coupled to the upper side of the heater plate 321 to correspond to the edge of the heater plate 321, and a portion of the sealing plate 323 is coupled to the bottom 221 and the side wall of the main body 220. Part 223 can be joined through an interview.

That is, a part of the heater plate 321 is coupled to cover the edge of the heater plate 321 and the bottom 221 of the main body 220, preventing water particles from leaking out from the heating space S3. can be prevented.

Meanwhile, in this case, it may be formed to contact the upper surface of the second step portion 224 formed with a step at the outermost portion of the bottom portion 221 of the main body portion 220, and by combining with the heater plate 321. , it can block external leakage of water particles through the coupling surface.

The supply pipe 330 is a configuration that receives water from the outside and supplies it to the heating space (S3), and various configurations are possible.

For example, the supply pipe 330 is configured to supply water from the outside to form humidifying particles evaporated through the heater unit 320, and one end is connected to a water supply device or water tank 3. And the other end may be connected to the housing portion 200.

More specifically, the supply pipe 330 is connected to the inlet 240 formed in the main body 220 and can supply water to the heating space S3.

The temperature sensor 500 is installed in the heater unit 320 to measure the temperature of the heater unit 320, and various configurations are possible.

For example, the temperature sensor 500 is installed in the heater unit 320 and measures the temperature of the heater unit 320, thereby measuring the set temperature of the heater unit 320 set through the control unit 30 and the heater unit ( 320), the humidity of the gas can be controlled more precisely by comparing the temperature.

More specifically, the temperature sensor 500 measures the heating temperature through the temperature of the heater unit 320, and more precisely adjusts the temperature delivered to the water particles based on the measured heating temperature to increase the amount of humidifying particles. It is possible to precisely control the humidity of the gas, and furthermore, by understanding the temperature of the humidifying particles, the humidity, which is closely related to temperature, can be adjusted by considering comprehensive factors.

At this time, the temperature sensor 500 is provided adjacent to or in contact with the upper surface of the heater plate 321 where the heating wire unit 322 is disposed, and can measure the temperature of the heater unit 320.

Meanwhile, the temperature sensor 500 is electrically connected to the control unit 30, which will be described later, and provides the sensed temperature of the heater unit 320 to the control unit 30 to control the control unit (300) based on the temperature of the heater unit 320. The control signal of 30) can be transmitted to the heater unit 320.

In this case, the control signal can be corrected by considering the difference between the temperature of the heater unit 320 and the preset temperature of the control unit 30 based on the sensed temperature of the heater unit 320. As another example, the control signal can be corrected by taking into account the difference between the temperature of the heater unit 320 and the preset temperature of the control unit 30. The set value may be recalculated to compensate for the difference with the temperature of the heater unit 320.

Meanwhile, in this case, a humidity sensor may be installed in the supply pipe 100, and the humidity of the gas passing through the passage S1 and the gas containing humidifying particles may be measured and the measured value may be transmitted to the control unit 30.

In this case, the temperature of the heater unit 320 can be precisely controlled so that the gas has a humidity that is a preset target value by comprehensively considering the humidity value of the gas and the temperature of the heater unit 320.

The control unit 30 can control the humidity of the gas by measuring the temperature of the gas within the humidifier module 20.

For example, the control unit 30 can control the humidity of the gas by controlling the degree of atomization of water particles by controlling the heater unit 320 for generating humidifying particles in the humidifier module 20.

Furthermore, the control unit 30 controls the temperature of the humidifying particles by controlling the heater unit 320 for generating humidifying particles in the humidifier module 20 to precisely control the humidity of the gas through the amount and temperature of the humidifying particles. It can be adjusted accordingly.

Meanwhile, in this case, the control unit 30 can control the humidity of the gas by measuring the temperature of the heater unit 320 for generating humidifying particles in the humidifier module 20.

More specifically, the control unit 30 controls the humidity of the gas through a control signal that adjusts the target temperature value of the heater unit 320 based on the temperature of the heater unit 320 measured through the temperature sensor 500 described above. can be adjusted.

Hereinafter, the control method of the humidifier device according to the present invention will be described in detail.

The control method of the humidifier device according to the present invention includes a measurement step (S100) of directly or indirectly measuring the temperature and humidity of the gas in the humidifier module 20; It includes a humidity control step (S200) of controlling the humidity of the gas by controlling the humidifier module 20 through the control unit 30 based on the measured temperature and humidity of the gas.

The measurement step (S100) is a step of directly or indirectly measuring the temperature and humidity of the gas of the humidifier module 20, and can be performed using various methods.

For example, the measurement step (S100) measures the temperature and humidity of the gas in the humidifier module 20, and measures the humidity and temperature of the gas passing through the supply pipe 100 through the humidity and temperature sensor in the supply pipe 100. can be measured.

In addition, in the measurement step (S100), in order to indirectly measure the temperature and humidity of the gas of the humidifier module 20, the temperature of the heater unit 320 is measured based on the temperature sensor 500 installed in the heater unit 320. can be measured.

The humidity control step (S200) is based on the temperature and humidity of the gas of the humidifier module 20 measured through the measurement step (S100), the target humidity value of the gas and the current humidity value of the gas set according to the user's settings. By comparing and calculating the difference value, and transmitting the control signal derived through the calculated value to the heater unit 320, the humidity can be controlled by controlling the amount and temperature of humidifying particles through the heater unit 320.

In this case, the humidity control step (S200) indirectly calculates the temperature and humidity of the gas based on the temperature of the heater unit 320 measured through the measurement step (S100) and compares it with the user's target value. Humidity can be adjusted, and furthermore, a control signal can be transmitted by correcting the difference between the actual temperature of the heater unit 320 and the set temperature through the control signal based on the measured temperature of the heater unit 320.

In addition, the humidifier module according to the present invention may additionally include a connector portion 600 for electrical connection with the control portion 30 described above.

The connector unit 600 can transmit control signals, etc. by electrically connecting the humidifier module to the humidifier module, particularly the control unit 30 for controlling the atomization unit 300.

Since the above is only a description of some of the preferred embodiments that can be implemented by the present invention, as is well known, the scope of the present invention should not be construed as limited to the above embodiments, and the scope of the present invention described above Both the technical idea and the technical idea underlying it will be said to be included in the scope of the present invention.

10: gas tube 100: supply pipe
200: housing part 300: atomization part
400: Sealing member 500: Temperature sensor

Claims (13)

a supply pipe (100) in which a gas tube (10) is coupled at both ends to form a passage (S1) through which the gas supplied to the patient passes;
A housing portion 200 in which an internal space S2 is formed and a communication port 210 is formed so that the internal space S2 communicates with the passage passage S1;
It is installed in the internal space (S2) and includes an atomization unit (300) that atomizes water supplied from the outside into fine humidifying particles and supplies it to the passage passage (S1),
The atomization unit 300,
a filter unit 310 installed to cover the communication port 210 in the internal space S2;
a heater unit 320 that is installed upwardly and spaced apart from the filter unit 310 to form a heating space (S3) between the filter unit 310 and heats water supplied to the heating space (S3);
It includes a supply pipe 330 that receives water from the outside and supplies it to the heating space (S3),
The filter unit 310,
A filter 311 forms the heating space S3 and passes the humidifying particles, and is installed in the communication port 210 between the supply pipe 100 and the filter 31 to lower the filter 311. It includes a filter plate 312 made of mesh material supported by,
The heater unit 320,
It includes a heater plate 321 installed parallel to the filter unit 310 to form the heating space S3, and a heating wire unit 322 installed on the heater plate 321 to generate heat,
The heater unit 320,
It additionally includes a sealing member 400 installed at the edge to seal the heating space S3,
The housing portion 200,
A communication port 210 formed with one side open to communicate with the supply pipe 100, a main body portion 220 provided in the vertical direction of the gas movement direction among the supply pipe 100, and the main body portion 220 It includes an opening 230 that is joined at the upper side to form an internal space (S2),
The main body 220,
It includes a bottom portion 221 where the communication opening 210 is formed, and a stepped portion 222 formed to have a step at an edge of the bottom portion 221,
The sealing member 400 is,
It is installed in close contact between the edge of the heater plate 321 supported on the step portion 222 and the bottom portion 221 on the outside of the step portion 222,
The housing portion 200,
It covers at least a portion of the cover portion 230 and the main body portion 220, and has a plurality of protrusions 251 protruding toward the cover portion 230 to form an insulating space between the cover portion 230 and the cover portion 230. It includes a cover portion 250 formed,
At least some of the plurality of protrusions 251 are inserted into the cover part 230 so that the cover part 250 is installed in the correct position with respect to the cover part 230, and the cross-sectional area increases toward the cover part 230. A humidifier module characterized by a shrinking wedge shape. In claim 1,
The housing portion 200,
A humidifier module, characterized in that it is provided in a direction perpendicular to the gas movement direction among the supply pipes (100). delete delete delete delete In claim 1,
A humidifier module comprising a temperature sensor 500 installed in the heater unit 320 to measure the temperature of the heater unit 320. A gas tube (10) with one end connected to the patient side and the other end connected to a gas supply device (2) that supplies gas to the patient;
A humidifier module according to any one of claims 1, 2, and 7, which is installed in the gas tube (10) and supplies humidifying particles to the gas supplied to the patient through the gas tube (10). (20) and;
A humidifier device comprising a control unit (30) connected to the humidifier module (20) and controlling the humidity of the gas by controlling the humidifier module (20). In claim 8,
The humidifier module 20,
A humidifier device, characterized in that it is provided adjacent to the patient side of the gas tube (10). In claim 8,
The control unit 30,
A humidifier device characterized in that the humidity of the gas is controlled by measuring the temperature of the gas within the humidifier module (20). In claim 8,
The control unit 30,
A humidifier device characterized in that the humidity of the gas is adjusted by measuring the temperature of the heater unit (320) for generating humidifying particles in the humidifier module (20). As a control method of a humidifier device according to claim 8,
A measurement step (S100) of directly or indirectly measuring the temperature and humidity of the gas in the humidifier module 20;
A humidifier device control method comprising a humidity control step (S200) of controlling the humidity of the gas by controlling the humidifier module 20 through the control unit 30 based on the measured temperature and humidity of the gas. . In claim 12,
In the measurement step (S100),
A humidifier device control method characterized in that the temperature of the heater unit 320 is measured based on the temperature sensor 500 installed in the heater unit 320.

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